Neutrophil progenitors and related methods and uses

Identifying and isolating neutrophil progenitors using biomarkers addresses the slow neutrophil generation in HSCT, enhancing immune protection and reducing infection-related morbidity and costs.

US12650428B2Active Publication Date: 2026-06-09AGENCY FOR SCI TECH & RES

Patent Information

Authority / Receiving Office
US · United States
Patent Type
Patents(United States)
Current Assignee / Owner
AGENCY FOR SCI TECH & RES
Filing Date
2021-06-11
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

Current methods for generating neutrophils from stem cells in hematopoietic stem cell transplantation are slow, leading to neutropenia and increased morbidity and mortality due to infections, and existing treatments like antimicrobial drugs and recombinant growth factors are ineffective and costly.

Method used

A method for identifying and isolating neutrophil progenitors using specific biomarkers (CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b, and CD49d) and enriching them from cell populations, followed by culturing to obtain neutrophil progenies for administration to subjects in need.

Benefits of technology

Facilitates rapid generation of neutrophils, reducing the risk of infections and associated healthcare costs by providing effective immune protection during the neutropenic period.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

There is provided a method of identifying a neutrophil progenitor, the method comprising: determining an expression of at least one biomarker selected from the group consisting of: CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and CD49d in a cell. In various embodiments, the cell is identified as a neutrophil progenitor when it is determined to have at least one of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +. Also disclosed are a method of sorting and / or separating neutrophil progenitors from a cell population, a composition that is enriched in neutrophil progenitors and related uses and methods.
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Description

[0001] This application is the U.S. National Stage of International Application No. PCT / SG2021 / 050342, filed Jun. 11, 2021, which designates the U.S., published in English, and claims priority under 35 U.S.C. § 119 or 365(c) to Singapore Application No. 10202005589P, filed Jun. 12, 2020. The entire teachings of the above applications are incorporated herein by reference.TECHNICAL FIELD

[0002] The present disclosure relates broadly to a granulocyte-monocyte progenitor (GMP) subpopulation, such as neutrophil progenitors, and related methods and uses.BACKGROUND

[0003] Hematopoietic Stem Cell Transplantation (HSCT) is a common treatment for hematological disorders and neoplastic diseases. However, the generation of neutrophils, which are important immune cells that provide protection against bacterial and fungal infections, from stem cells is a long process that takes an estimated 3-4 weeks in human. Thus, neutropenia after transplantation often leads to morbidity and mortality caused by infections. Current clinical management involves administration of prophylactic antimicrobial drugs, recombinant growth factors (e.g., G-CSF) or repeated Donor Granulocyte Infusion (DGI) in isolation wards to provide immune protection for patients during the neutropenic period, which can be ineffective and associated with high healthcare costs.

[0004] Thus, there is a need to address or at least ameliorate one or more of the above-mentioned problems. In particular, there is a need to provide a method of identifying a neutrophil progenitor, a method of sorting and / or separating neutrophil progenitors from a cell population, a composition that is enriched in neutrophil progenitors and related uses and methods that address or at least ameliorate one or more of the above-mentioned problems.SUMMARY

[0005] In one aspect, there is provided a method of identifying a neutrophil progenitor, the method comprising: determining an expression of at least one biomarker selected from the group consisting of: CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and CD49d in a cell; and identifying the cell as a neutrophil progenitor when it is determined to have at least one of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +.

[0006] In one embodiment, the biomarker comprises CD71 and the cell is identified to be a neutrophil progenitor when it is determined to have CD71hi / + expression.

[0007] In one embodiment, where the cell is identified as a neutrophil progenitor, the method further comprises: determining an expression of a further biomarker selected from CD49d and / or a side-scatter (SSC) property of the neutrophil progenitor; and identifying a subtype of the neutrophil progenitor based on the expression of the further biomarker and / or the side-scatter property.

[0008] In one embodiment, where the neutrophil progenitor is determined to be CD49dhi / + and / or SSClo, the neutrophil progenitor is identified as an early committed neutrophil progenitor, and wherein where the neutrophil progenitor is determined to be CD49dint / lo / − and / or SSChi, the neutrophil progenitor is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor.

[0009] In one embodiment, determination of the expression of the at least one biomarker and / or the further biomarker comprises contacting the cell with one or more antibodies against the biomarker and / or the further biomarker.

[0010] In one aspect, there is provided a method of sorting and / or separating neutrophil progenitors from a cell population, the method comprising: selecting for cells having at least one of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +.

[0011] In one embodiment, the method comprises selecting for CD71hi / + cells.

[0012] In one embodiment, the cell population is derived from cord blood and / or bone marrow.

[0013] In one embodiment, the method further comprises culturing the neutrophil progenitors to obtain proliferation and / or differentiation of the neutrophil progenitors to obtain progenies thereof.

[0014] In one embodiment, the method further comprises administering the neutrophil progenitors and / or the progenies thereof to a subject in need thereof.

[0015] In one embodiment, the subject has neutropenia.

[0016] In one embodiment, the selecting step comprises contacting the cells with one or more antibodies against one or more of CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and CD49d.

[0017] In one aspect, there is provided a composition that is enriched in neutrophil progenitors having at least one of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +.

[0018] In one embodiment, the composition is enriched in CD71hi / + neutrophil progenitors.

[0019] In one aspect, there is provided the composition for use in therapy.

[0020] In one aspect, there is provided the composition for use in treating neutropenia.

[0021] In one aspect, there is provided use of the composition in the manufacture of a medicament for treating neutropenia.

[0022] In one aspect, there is provided a method of preparing a transfusion composition, the method comprising: enriching a composition for neutrophil progenitors having at least one of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11lo / − and / or CD49dint / hi / +.

[0023] In one embodiment, the method comprises enriching the composition for CD71hi / + neutrophil progenitors.

[0024] In one embodiment, the enriching step comprises contacting the composition with one or more antibodies against one or more of CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and CD49d.Definitions

[0025] The term “treatment”, “treat” and “therapy”, and synonyms thereof as used herein refer to both therapeutic treatment and prophylactic or preventative measures, wherein the object is to prevent or slow down (lessen) a medical condition, which includes but is not limited to diseases, symptoms and disorders. A medical condition also includes a body's response to a disease or disorder, e.g., inflammation. Those in need of such treatment include those already with a medical condition as well as those prone to getting the medical condition or those in whom a medical condition is to be prevented.

[0026] As used herein, the term “therapeutically effective amount” of a compound will be an amount of an active agent that is capable of preventing or at least slowing down (lessening) a medical condition, such as neutropenia. Dosages and administration of compounds, compositions and formulations of the present disclosure may be determined by one of ordinary skill in the art of clinical pharmacology or pharmacokinetics. See, for example, Mordenti and Rescigno, (1992) Pharmaceutical Research. 9:17-25; Morenti et al., (1991) Pharmaceutical Research. 8:1351-1359; and Mordenti and Chappell, “The use of interspecies scaling in toxicokinetics” in Toxicokinetics and New Drug Development, Yacobi et al. (eds) (Pergamon Press: NY, 1989), pp. 42-96. An effective amount of the active agent of the present disclosure to be employed therapeutically will depend, for example, upon the therapeutic objectives, the route of administration, and the condition of the patient. Accordingly, it may be necessary for the therapist to titer the dosage and modify the route of administration as required to obtain the optimal therapeutic effect.

[0027] The term “subject” as used herein includes patients and non-patients. The term “patient” refers to individuals suffering or are likely to suffer from a medical condition such as cancer, while “non-patients” refer to individuals not suffering and are likely to not suffer from the medical condition. “Non-patients” include healthy individuals, non-diseased individuals and / or an individual free from the medical condition. The term “subject” includes humans and animals. Animals include murine and the like. “Murine” refers to any mammal from the family Muridae, such as mouse, rat, and the like.

[0028] As used herein, an “expression” refers to both genotypic as well as phenotypic expression of biomarkers in the present disclosure.

[0029] A “biomarker” refers to a molecule, for example, a protein, carbohydrate structure, glycolipid, glycoprotein (including cell surface glycoprotein), receptor (including cell surface receptor) or gene (or nucleic acid encoding the gene), the expression of which in or on a cell (or sample) derived from a subject (such as a mammalian tissue) can be detected by standard methods in the art (as well as those disclosed herein). In some examples, a biomarker may be any molecule that may serve as an identifier (i.e., marker) of a target of interest. In some examples, a biomarker may be a cell surface receptor, a cell surface glycoprotein, a transcription factor, and the like. In some examples, the biomarker may be used to classify, identify, detect, isolate, purify, enrich, select, sort, and / or separate a cell / cell population, and / or determine a stage of differentiation, a stage of development and / or activity state of a cell.

[0030] In some examples, where the biomarker comprises a cell surface marker, the expression of the marker may be denoted in accordance to the acceptable denotation known in common general knowledge. For example, for a cell surface marker CD71, a CD71+ refers to the cell positively expressing CD71, a CD71− refers to the cell not expressing detectable CD71, CD71lo refers to the cell expressing low CD71, CD71int refers to the cell expressing intermediate CD71, and CD71hi refers to the cell expressing high CD71.

[0031] As used in the specification herein, agents for detecting biomarkers in the present disclosure refer to any compound, molecule and / or system that functions to detect the presence / absence and / or expression or level thereof of biomarkers in the present disclosure. Such agents are capable of detecting and / or binding directly or indirectly to a biomarker. In the present disclosure, additional moieties may be required to enhance the detection of the biomarkers, for example, by / through amplifying optical diffraction. Examples of agents and the additional moieties include but are not limited to proteins (for example antigen binding proteins such as antibodies or fragments thereof, enzymes such as horseradish peroxides and alkaline phosphatase, and the like), polynucleotides (for example aptamers), and small molecules (for example metallic nanoparticles).

[0032] The term “micro” as used herein is to be interpreted broadly to include dimensions from about 1 micron to about 1000 microns.

[0033] The term “nano” as used herein is to be interpreted broadly to include dimensions less than about 1000 nm.

[0034] The term “particle” as used herein broadly refers to a discrete entity or a discrete body. The particle described herein can include an organic, an inorganic or a biological particle. The particle used described herein may also be a macro-particle that is formed by an aggregate of a plurality of sub-particles or a fragment of a small object.

[0035] The particle of the present disclosure may be spherical, substantially spherical, or non-spherical, such as irregularly shaped particles or ellipsoidally shaped particles. The term “size” when used to refer to the particle broadly refers to the largest dimension of the particle. For example, when the particle is substantially spherical, the term “size” can refer to the diameter of the particle; or when the particle is substantially non-spherical, the term “size” can refer to the largest length of the particle.

[0036] The terms “coupled” or “connected” as used in this description are intended to cover both directly connected or connected through one or more intermediate means, unless otherwise stated.

[0037] The term “associated with”, used herein when referring to two elements refers to a broad relationship between the two elements. The relationship includes, but is not limited to a physical, a chemical or a biological relationship. For example, when element A is associated with element B, elements A and B may be directly or indirectly attached to each other or element A may contain element B or vice versa.

[0038] The term “adjacent” used herein when referring to two elements refers to one element being in close proximity to another element and may be but is not limited to the elements contacting each other or may further include the elements being separated by one or more further elements disposed therebetween.

[0039] The term “and / or”, e.g., “X and / or Y” is understood to mean either “X and Y” or “X or Y” and should be taken to provide explicit support for both meanings or for either meaning.

[0040] Further, in the description herein, the word “substantially” whenever used is understood to include, but not restricted to, “entirely” or “completely” and the like. In addition, terms such as “comprising”, “comprise”, and the like whenever used, are intended to be non-restricting descriptive language in that they broadly include elements / components recited after such terms, in addition to other components not explicitly recited. For example, when “comprising” is used, reference to a “one” feature is also intended to be a reference to “at least one” of that feature. Terms such as “consisting”, “consist”, and the like, may in the appropriate context, be considered as a subset of terms such as “comprising”, “comprise”, and the like. Therefore, in embodiments disclosed herein using the terms such as “comprising”, “comprise”, and the like, it will be appreciated that these embodiments provide teaching for corresponding embodiments using terms such as “consisting”, “consist”, and the like. Further, terms such as “about”, “approximately” and the like whenever used, typically means a reasonable variation, for example a variation of + / −5% of the disclosed value, or a variance of 4% of the disclosed value, or a variance of 3% of the disclosed value, a variance of 2% of the disclosed value or a variance of 1% of the disclosed value.

[0041] Furthermore, in the description herein, certain values may be disclosed in a range. The values showing the end points of a range are intended to illustrate a preferred range. Whenever a range has been described, it is intended that the range covers and teaches all possible sub-ranges as well as individual numerical values within that range. That is, the end points of a range should not be interpreted as inflexible limitations. For example, a description of a range of 1% to 5% is intended to have specifically disclosed sub-ranges 1% to 2%, 1% to 3%, 1% to 4%, 2% to 3% etc., as well as individually, values within that range such as 1%, 2%, 3%, 4% and 5%. It is to be appreciated that the individual numerical values within the range also include integers, fractions and decimals. Furthermore, whenever a range has been described, it is also intended that the range covers and teaches values of up to 2 additional decimal places or significant figures (where appropriate) from the shown numerical end points. For example, a description of a range of 1% to 5% is intended to have specifically disclosed the ranges 1.00% to 5.00% and also 1.0% to 5.0% and all their intermediate values (such as 1.01%, 1.02% . . . 4.98%, 4.99%, 5.00% and 1.1%, 1.2% . . . 4.8%, 4.9%, 5.0% etc.,) spanning the ranges. The intention of the above specific disclosure is applicable to any depth / breadth of a range.

[0042] Additionally, when describing some embodiments, the disclosure may have disclosed a method and / or process as a particular sequence of steps. However, unless otherwise required, it will be appreciated that the method or process should not be limited to the particular sequence of steps disclosed. Other sequences of steps may be possible. The particular order of the steps disclosed herein should not be construed as undue limitations. Unless otherwise required, a method and / or process disclosed herein should not be limited to the steps being carried out in the order written. The sequence of steps may be varied and still remain within the scope of the disclosure.

[0043] Furthermore, it will be appreciated that while the present disclosure provides embodiments having one or more of the features / characteristics discussed herein, one or more of these features / characteristics may also be disclaimed in other alternative embodiments and the present disclosure provides support for such disclaimers and these associated alternative embodiments.DESCRIPTION OF EMBODIMENTS

[0044] Exemplary, non-limiting embodiments of a method of characterising / identifying a granulocyte-monocyte progenitor (GMP) population, such as a neutrophil progenitor subpopulation, and related compositions, methods and kits are disclosed hereinafter.

[0045] GMPs are known to give rise to granulocytes (such as neutrophils, eosinophils, and basophils) and monocytes. In some examples, GMPs are found to contain a mixed population of monocytic, neutrophilic, eosinophilic and basophilic progenitor subsets. In various embodiments, there is provided a method of classifying, identifying, detecting, isolating, purifying, enriching, selecting, sorting and / or separating a GMP cell / population / subpopulation / subset and / or determining a stage of differentiation, a stage of development and / or activity state of a cell / population / subpopulation / subset. GMP subpopulations (or subsets) may include a monocytic progenitor subpopulation, a neutrophilic progenitor subpopulation, an eosinophilic progenitor subpopulation and a basophilic progenitor subpopulation. Further distinct subpopulations (or subsets) may exist within these progenitor subpopulations.

[0046] In various embodiments, the method comprises determining a transcriptomic profile and / or proteomic profile of the cell / population / subpopulation / subset. In various embodiments, the method comprises determining and / or measuring the presence / absence / amount / level / proportion of one or more markers / biomarkers / signatures in the cell / population / subpopulation / subset. In various embodiments, the method comprises determining and / or measuring one or more physical properties of the cell / population / subpopulation / subset. The determination or measurement may be quantitative, semi-quantitative or qualitative.

[0047] In various embodiments, the method comprises determining or measuring the presence / absence / amount / level / proportion of at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven, at least about eight, at least about nine or at least about ten markers / biomarkers and / or physical properties associated with the cell / population / subpopulation / subset. In various embodiments, the method comprises determining or measuring the presence / absence / amount / level / proportion of no more than about ten, no more than about nine, no more than about eight, no more than about seven, no more than about six, no more than about five, no more than about four, no more than about three, no more than two or not more than about one marker / biomarker and / or physical property associated with the cell / population / subpopulation / subset.

[0048] Markers / biomarkers / signature or a component thereof include, but are not limited to, polypeptides (e.g., cell surface proteins) and polynucleotides (e.g., DNA and RNA). The markers / biomarkers / signature may be transcriptomic and / or proteomic markers / biomarkers / signatures. In some embodiments, the marker comprises an RNA marker / biomarker / signature. In some embodiments, the marker comprises a protein marker / biomarker / signature. In some embodiments, the marker comprises a surface / cell surface marker / biomarker / signature. In some embodiments, the marker comprises a transcription factor.

[0049] In various embodiments, the marker / biomarker / signature is selected from the group consisting of: 33D1, 4-11BB Ligand, APCDD1, B220, B7H4, B7-H4, C3aR, Cadherin 11, CCR10, CCRL2, CCX-CKR (CCRL1), CD10, CD100, CD102, CD103, CD104, CD105 (Endoglin), CD106, CD107a, CD107b, CD109, CD111, CD112, CD114, CD115, CD116, CD117, CD119, CD11a, CD11b, CD11c, CD120a, CD120b, CD121a, CD122, CD123, CD124, CD126, CD127, CD129, CD13, CD130, CD131, CD132, CD133, CD134, CD135, CD137, CD138, CD14, CD140a, CD140b, CD141, CD142, CD143, CD144, CD146, CD147, CD148, CD15, CD150, CD151, CD152, CD152 (CTLA-4), CD153, CD154, CD155, CD156c, CD157, CD158, CD158b, CD158e1, CD159a, CD16, CD16.2, CD160, CD161, CD162, CD163, CD164, CD165, CD166, CD169, CD170, CD172a (SIRPα), CD172b (SIRPβ), CD172g (SIRPγ), CD178, CD179a, CD179b, CD18, CD180, CD181, CD182, CD183, CD184, CD185, CD186, CD186 (CXCR6), CD19, CD191, CD192, CD193, CD194, CD195, CD196, CD197, CD198, CD199, CD1a, CD1b, CD1c, CD1d, CD2, CD20, CD200, CD200R, CD200R3, CD201, CD202b, CD203c, CD205, CD206, CD207, CD209, CD21, CD210, CD213α1, CD213α2, CD215, CD217, CD218a, CD22, CD220, CD220R, CD221, CD223 (LAG-3), CD226, CD227, CD229, CD23, CD230 (Prion), CD235ab, CD24, CD243, CD244 (2B4), CD245, CD25, CD252, CD253, CD254, CD255, CD258, CD26, CD261, CD262, CD263, CD265, CD266, CD267, CD268, CD269, CD27, CD272, CD273, CD274, CD275, CD276, CD277, CD278, CD279, CD28, CD282, CD284, CD29, CD290, CD294, CD298, CD3, CD30, CD300c, CD300d, CD300LG, CD301, CD301b, CD303, CD304, CD307e, CD309, CD31, CD314, CD317, CD318, CD319, CD32, CD323, CD324, CD325, CD326, CD328, CD33, CD334, CD335, CD336, CD337, CD338, CD339, CD34, CD34_MEC14.7, CD34_SA376A4, CD340, CD344, CD35, CD351, CD352, CD354, CD355, CD357, CD36, CD360, CD365, CD366, CD368, CD369, CD36L1, CD37, CD370, CD371, CD38, CD39, CD3e, CD4, CD40, CD41, CD42b, CD43, CD44, CD45, CD45.1, CD45.2, CD45RA, CD45RB, CD45RO, CD46, CD47, CD48, CD49a, CD49b, CD49c, CD49d, CD49e, CD49f, CD5, CD50, CD51, CD52, CD54, CD55, CD56 (NCAM), CD57, CD58, CD59, CD59a, CD6, CD61, CD62L, CD62P, CD63, CD64, CD66a, CD66b, CD66c, CD66e, CD69, CD7, CD70, CD71, CD73, CD74, CD79b, CD80, CD81, CD82, CD83, CD84, CD85, CD85d, CD85h, CD85k, CD86, CD87, CD88, CD89, CD8a, CD8b, CD9, CD90, CD90.1, CD90.2, CD92, CD93, CD94, CD95, CD96, CD97, CD98, CD99, cKit, CLEC4A, CX3CR1, CXCL16, CXCR7, DcTRAIL R1, Delta Opioid Receptor, Delta-like 1 (DLL1), Delta-like 4 (DLL4), Dopamine Receptor D1 (DRD1), DR3, E-Cadherin, EGFR, EphA2, erbB3, ESAM, F4 / 80, FcεRlα, FLT3, FPR3, FR4, Galectin9, Ganglioside GD2, GARP, GITR Ligand, GL7, GPR19, GPR56, GPR83, Gr1, H2, HLA-A, HLA-B, HLA-C, HLA-DR, HLA-E, HVEM, IA / IE, IFNAR1, IFNgR b chain, IFN-γ R b chain, Ig light chain κ, Ig light chain λ, IgD, IgG Fc, IgM, IL21R, IL23R, IL-28RA, IL33R, IL33Ra, Integrin α9β1, integrin β5, Integrin β7, Isotype AHIgG, Isotype mIgG1, Isotype mIgG2a, Isotype mIgG2b, Isotype mIgM, Isotype rIgG1, Isotype rIgG2a, Isotype rIgG2b, Isotype rIgG2c, Isotype rIgM, Isotype SHIgG, Jagged 2, JAML, KLRG1, Ksp37, LAP, LOX-1, LPAM_1, Ly-49A, Ly108, Ly49CFIH, Ly49D, Ly49H, Ly51, Ly6C, Ly6D, Ly6G, LY6G6D, Ly6K, Lymphotoxin β Receptor, Mac2, Mac3, MAdCAM1, MAIR-IV, MAIRV, MD1, MERTK, MICA, MICB, MRGX2, MSC, MUC-13, NK1.1, NKG2D, NKp80, Notch 1, Notch 2, Notch 3, Notch 4, Notch3, NPC, PD1H, PDC-TREM, PIR A, PIR B, Plexin B2, Podoplanin, PSMA, RAE1y, Sca-1, Sialyl Lewis X (dimeric), Siglec H, Siglec-10, Siglec-8, Siglec-9, SiglecF, SiglecH, SSC, SSEA-1, SSEA-3, SSEA-4, SSEA-5, SUSD2, TACSTD2, TCR gd, TCR Vd1.1_1.2, TCR α, TCR β, TCRb chain, TER119, TIGIT (VSTM3), Tim-2, Tim-4, TLR4, TLT-2, TM4SF20, TMEM8A, TNAP, TRA-1-60-R, TRA-1-81, TRA-2-49, TRA-2-54, Trem-like 4, TSLPR, VEGFR-3, VISTA and XCR1. In various embodiments, the markers / biomarkers / signature comprises one discussed in the Examples section of the present disclosure.

[0050] In some examples, a population of early neutrophil progenitors is found to exist within GMPs, the population extending along the developmental trajectory towards mature neutrophils. In various embodiments therefore, there is provided a method of classifying, identifying, detecting, isolating, purifying, enriching, selecting, sorting and / or separating a neutrophil progenitor / neutrophil progenitor population and / or determining a stage of differentiation, a stage of development and / or activity state of a neutrophil progenitor / neutrophil progenitor population. In various embodiments, the neutrophil progenitor comprises a committed neutrophil progenitor. For example, the neutrophil progenitor may be incapable of differentiating into a cell of a non-neutrophil lineage, such as a monocyte, under physiological conditions. In some examples, neutrophil progenitors give rise to Ly6G+ neutrophils but not macrophages when cultured with a factor (e.g., CSF-1) that promotes differentiation towards the monocytic lineage. Thus, while a neutrophil progenitor may differentiate (exclusively) along the neutrophil lineage (for example, to give rise to a pre-neutrophil (preNeu), an immature neutrophil or a mature neutrophil), a neutrophil progenitor may not differentiate into a cell of a non-neutrophil lineage. In various embodiments, the neutrophil progenitor is capable of generating mature neutrophils, for example, CD16+CD10+ mature neutrophils. In various embodiments, the neutrophil progenitor comprises an early neutrophil progenitor (e.g., a neutrophil progenitor that is upstream of preNeu and other neutrophil precursors in neutrophil lineage). In various embodiments, the neutrophil progenitor has a high proliferative capacity (e.g., higher proliferative capacity than preNeu and other neutrophil precursors).

[0051] The neutrophil progenitor may be that of an animal or a human. In some embodiments, the neutrophil progenitor comprises the neutrophil progenitor of a mammal (e.g., humans, non-human primates, canine, murine (e.g., mouse, rat, rabbit etc.) and the like). In some embodiments, the neutrophil progenitor comprises a mouse neutrophil progenitor. In some embodiments, the neutrophil progenitor comprises a human neutrophil progenitor.

[0052] In various embodiments, there is provided a method of identifying a neutrophil progenitor, the method comprising: determining an expression of at least about one, at least about two, at least about three, at least about four, at least about five or at least about six, at least about seven, at least about eight, at least about nine, at least about ten, at least about 11, at least about 12, at least about 13, at least about 14 or at least about 15 biomarker(s) selected from the group consisting of: CD71, LOX-1, CD164, CD112, CD181, TACSTD2, Ly6C, CD115, CD11b, CD34, CD81, CD49a, CD49d, CD106 and CD63 in a cell. In various embodiments, there is provided a method of identifying a neutrophil progenitor, the method comprising: determining an expression of at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight biomarker(s) selected from the group consisting of: CD71 (transferrin receptor protein 1), LOX-1 (lectin-type oxidized low-density lipoprotein (LDL) receptor-1), CD164 (sialomucin core protein 24 or endolyn or cluster of differentiation 164), CD112 (poliovirus receptor-related 2 (PVRL2) or nectin-2), CD181 (Interleukin 8 receptor alpha or cluster of differentiation 181), TACSTD2 (Tumor Associated Calcium Signal Transducer 2), CD11b (Integrin alpha M or cluster of differentiation molecule 11 b) and CD49d (Integrin α4) in a cell. The cell may be a GMP cell (e.g., a cell having one or more of the following expression profiles: Lin−, cKit+, Sca-1−, CD34hi / +, and CD16 / 32hi) a bone marrow cell (e.g., a fetal bone marrow cell) or a cord blood cell. The cell may be an animal cell or a human cell. In various embodiments, where the cell is determined to be CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +, the cell is identified to be a neutrophil progenitor. In various embodiments therefore, the method comprises: determining an expression of at least one biomarker selected from the group consisting of: CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and CD49d in a cell; and identifying the cell as a neutrophil progenitor when it is determined to have at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11lo / − and / or CD49dint / hi / +. Advantageously, the biomarkers disclosed herein are found to be capable to distinguishing a neutrophil progenitor from cells of other types or from a heterogenous cell population (e.g., a GMP population). In other words, a neutrophil progenitor may be characterized or identified by the expression of one or more of these biomarkers.

[0053] In one embodiment, the biomarker comprises CD71. In one embodiment therefore, the cell is identified to be a neutrophil progenitor when it is determined to express CD71 or when it is determined to be CD71hi / +. In various embodiments therefore, there is provided a method of identifying a neutrophil progenitor, the method comprising: determining an expression of CD71 in a cell; and identifying the cell as a neutrophil progenitor when it is determined express CD71. In some examples, CD71 is found to be exclusively expressed by neutrophil progenitors among total cord blood cells.

[0054] In some embodiments, the method may comprise determining an expression of a transcription factor in the cell. In some embodiments, the method may comprise determining an expression of at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, or at least about seven transcription factor(s) selected from the group consisting of: Jag1, Sox13, Gfi1, Per3, Cebpe, Ets1 and Gata1 in the cell.

[0055] Among neutrophil progenitors (termed as proNeus), the inventors found two phenotypically distinct neutrophil progenitors (termed as proNeu1 and proNeu2). In various examples, proNeu1 was found to possess higher self-renewing potential / properties and / or enhanced colony forming potential than proNeu2. In various examples, transcriptomic pathway analysis supported the decrease in progenitor function of proNeu2, showing an exclusive enrichment in neutrophil effector functions, while proNeu1 was enriched in cellular components and cell survival. In various examples, proNeu1 increased in numbers while proNeu2 remained largely unchanged during the course of an infection in a sepsis / inflammation model. In various examples, proNeu2 is shown to be a bridging point between proNeu1 and preNeu. In various examples, proNeu1 is shown to give rise to proNeu2 and subsequent neutrophil subsets and proNeu2 is shown to specifically give rise to preNeus and immature Neus. In various examples, proNeu1 is shown to exclusively give rise to downstream neutrophil subsets through a C / EBPε-dependent proNeu2 development. In various examples, proNeu1 is shown to be an early committed neutrophil and proNeu2 is shown to be an intermediate neutrophil progenitor that is downstream in neutrophil lineage to proNeu1.

[0056] In various embodiments therefore, where the cell is identified as a neutrophil progenitor, the method further comprises determining a subtype of the neutrophil progenitor. Determining a subtype of the neutrophil progenitor may comprise determining / measuring an expression of further biomarker(s) in the cell and / or one or more physical property associated with the cell.

[0057] In various embodiments, determining / measuring an expression of further biomarker(s) in the cell comprises determining at least about one, at least about two, at least about three or at least about four biomarker(s) selected from the group consisting of: CD49d, CD34, CD106, CD11b in the cell. In various embodiments, the cell is identified as an early committed neutrophil when it is determined to have one or more of the following expression profiles: CD49dhi / +, CD34hi / +, CD106lo / − and CD11blo / −. In various embodiments, the cell is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor when it is determined to have one or more of the following expression profiles: CD49dint / lo / −, CD34lo / −, CD106hi / + and CD11bhi / +.

[0058] In various embodiments, determining / measuring one or more physical property associated with the cell comprises determining / measuring a granularity or complexity of the cell and / or a nucleus morphology of the cell. In various embodiments, the cell is identified as an early committed neutrophil when it is determined to have no or minimal hollowing of the nucleus that falls below a threshold diameter. In various embodiments, the cell is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor when it is determined to have a hollowing of the nucleus that corresponds to or exceeds the threshold diameter. In various embodiments, the cell is identified as an early committed neutrophil when it is determined to have low granularity or complexity. In various embodiments, the cell is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor when it is determined to have high granularity or complexity. Granularity or complexity may be determined / measured by, for example, by evaluating a side-scatter property in flow cytometry. In various embodiments therefore, the cell is identified as an early committed neutrophil when it is determined to have low side scatter. In various embodiments therefore, the cell is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor when it is determined to have high side scatter.

[0059] In some embodiments, where the cell is identified as a neutrophil progenitor, the method further comprises determining an expression of a further biomarker selected from CD49d and / or a side-scatter property of the neutrophil progenitor; and identifying a subtype of the neutrophil progenitor based on the expression of the further biomarker and / or the side-scatter property. In various embodiments, where the cell is determined to have CD49dhi / + expression, the cell is identified as an early committed neutrophil progenitor. In various embodiments, where the cell is determined to have CD49dint / lo / − expression, the cell is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor. In various embodiments, where the cell is determined to have low side scatter, the cell is identified as an early committed neutrophil progenitor. In various embodiments, where the cell is determined to have high side scatter, the cell is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor. In various embodiments therefore, where the neutrophil progenitor is determined to be CD49dhi / + and / or SSClo, the neutrophil progenitor is identified as an early committed neutrophil progenitor, and wherein where the neutrophil progenitor is determined to be CD49dint / lo / − and / or SSChi, the neutrophil progenitor is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor. Embodiments of the method may also be used to determine a stage of differentiation and / or development of a neutrophil progenitor. For example, a neutrophil progenitor that is determined to be CD49dhi / + and / or SSClo may be identified as being in an earlier stage of differentiation and / or development than a neutrophil progenitor that is determined to be CD49dint / lo / − and / or SSChi.

[0060] The expression of the biomarker may be determined or measured by methods known in the art. In some embodiments, determining / measuring an expression of a biomarker in a cell comprises performing RNA sequencing such as single-cell RNA sequencing. In some embodiments, determining / measuring an expression of a biomarker in a cell comprises contacting / incubating the cell with an agent for detecting the biomarker, for example, a molecule capable of binding to the biomarker or having affinity for the biomarker. Examples of agents / molecules that may be employed include, but are not limited to, small molecules, peptides, proteins, antigen-binding proteins, antibodies, polynucleotides, aptamers, fragments thereof and the like. In some embodiments, determining / measuring an expression of a biomarker in a cell comprises contacting / incubating the cell with at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven, at least about eight, at least about nine or at least about ten agents / molecules. In some embodiments, determining / measuring an expression of a biomarker in a cell comprises contacting / incubating the cell with no more than about ten, no more than about nine, no more than about eight, no more than about seven, no more than about six, no more than about five, no more than about four, no more than about three, no more than two or not more than about one agent / molecule.

[0061] In various embodiments, the molecule comprises an antigen-binding molecule. Examples of antigen-binding molecules include, but are not limited to, antibodies and fragments thereof such as antigen binding fragments. Non-limiting examples of antigen binding fragments include one or more fragments or portions of an antibody that retain the ability to specifically bind to an antigen (e.g., CD71), or synthetic modifications of an antibody fragments that retain the desired binding ability to the antigen. In various embodiments, antigen binding fragments include single domain antibodies, further engineered molecules (such as, but is not limited to diabodies, triabodies, tetrabodies, minibodies, and the like), Fab fragments, Fab′ fragments, F(ab′)2 fragments, Fd fragments, Fv fragments, single-chain Fv (scFv) molecules, seFv molecules, scFv dimer, BsFv molecules, dsFv molecules, (dsFv)2 molecules, dsFv-dsFv′ molecules, Fv fragments, dAb fragments, bispecific antibodies, ds diabodies, nanobodies, domain antibodies, bivalent domain antibodies, and minimal recognition units consisting of the amino acid residues that mimic the hypervariable region of an antibody (e.g. an isolated complementarity determining region (CDR)).

[0062] In various embodiments, determination of the expression of the biomarker comprises contacting the cell with one or more antibodies against the biomarker. In various embodiments, the antibody is coupled or conjugated to a label, for example, a fluorescent label such as a fluorescent dye. In various embodiments, flow cytometry is performed to determine the expression of the biomarker.

[0063] In various embodiments, there is provided a method of sorting and / or separating neutrophil progenitors from a cell population or a method of enriching neutrophil progenitors in a cell population, the method comprising: selecting for cells having / expressing one or more of the biomarkers as described herein. In various embodiments, there is provided a method of sorting and / or separating neutrophil progenitors from a cell population, the method comprising: selecting for cells having at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +. In some embodiments, the method comprises selecting for CD71-expressing cells or CD71hi / + cells.

[0064] In various embodiments, the cell population is derived from cord blood and / or bone marrow. In various embodiments, the cell population is derived from fetal bone marrow. In various embodiments therefore, the cell population comprises or consists of cord blood cells, bone marrow cells and / or fetal bone marrow cells.

[0065] In various embodiments, the cord blood and / or bone marrow is collected from a mammal, such as, but not limited to, humans, non-human primates, canine, murine (e.g., mouse, rat, rabbit, and the like) and the like. In some embodiments, the cord blood and / or bone marrow is collected from a mouse or a human. In some embodiments therefore, the cell population comprises at least one selected from the group consisting of: mouse cord blood cells, mouse bone marrow cells, mouse fetal bone marrow cells, human cord blood cells, human bone marrow cells and human fetal bone marrow cells. In some embodiments, the cell population consists of mouse cord blood cells, mouse bone marrow cells, mouse fetal bone marrow cells, human cord blood cells, human bone marrow cells and / or human fetal bone marrow cells. In various examples, there is provided a method isolating a subset of neutrophil progenitors (proNeus) from human biological samples such as human cord blood and fetal bone marrow comprising the use of CD71 as a selection marker.

[0066] In various embodiments, the method further comprises culturing the neutrophil progenitors to obtain proliferation and / or differentiation of the neutrophil progenitors, for example, to mature neutrophils. In various embodiments, the mature neutrophils comprise CD16+CD10+ mature neutrophils.

[0067] In various embodiments, the method further comprises administering the neutrophil progenitors and / or progenies thereof (e.g., progenies resulting from the proliferation of the neutrophil progenitors and / or differentiation of the neutrophil progenitors) to a subject in need thereof. Examples of a subject in need thereof include, but is not limited to, a neutropenic subject, a subject having cancer, a subject having an infection (e.g., bacterial and / or fungal infections), a subject undergoing chemotherapy and / or radiation therapy, a subject having disorder of the blood, a subject having disorder of the bone marrow, a subject having disorder of the immune system, a subject who is a candidate for hematopoietic stem cell transplantation, a subject who is a candidate for myeloablative therapy and a subject having one or more of the following conditions: multiple myeloma, leukemia, lymphomas, aplastic anemia, thalassemia, sickle cell disease, severe combined immune deficiency syndrome and the like. In one embodiment, the subject has neutropenia.

[0068] In some embodiments, the cell population (i.e., the cell population which neutrophil progenitors is being separated from or in which neutrophil progenitors is being enriched in) is obtained / derived from the subject. In some embodiments therefore, the method further comprises a step of obtaining the cell population from the subject, for example, prior to a procedure such as hematopoietic stem cell transplantation or myeloablative therapy. In some embodiments, the cell population is obtained / derived from a donor.

[0069] In various embodiments, the selecting step comprises contacting / incubating the cell with agents for detecting the biomarker(s), for example, molecule(s) capable of binding to the biomarker(s) or having affinity for the biomarker(s) as described herein.

[0070] In some embodiments, the selecting step comprises contacting / incubating the cell with at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven, at least about eight, at least about nine or at least about ten agents / molecules. In some embodiments, the selecting step comprises contacting / incubating the cell with no more than about ten, no more than about nine, no more than about eight, no more than about seven, no more than about six, no more than about five, no more than about four, no more than about three, no more than two or not more than about one agent / molecule. In some embodiments, the molecule comprises an antibody. In various embodiments, the selecting step comprises contacting the cells with one or more antibodies against one or more of CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and / or CD49d. The antibody may be coupled or conjugated to a label, for example, a fluorescent label such as a fluorescent dye. In various embodiments, flow cytometry is performed to select for neutrophil progenitors. In various embodiments, fluorescence-activated cell sorting (FACS) is used to select for neutrophil progenitors.

[0071] In various embodiments, the method further comprises washing the cells. In various embodiments, the method further comprises removing the antibodies bound to the biomarkers. For example, the REAlease Releasable Antibody technology (Miltenyl Biotech) may be utilized. A REAlease Release Reagent may be added to allow the spontaneous dissociation of the antibodies bound. In various embodiments, the method further comprises expanding the cells (e.g., in vitro) to dilute the bound antibodies. In various embodiments, the method further comprises expanding the cells, and subsequently removing those cells with antibodies bound thereto. Advantageously, dilution and / or removal of antibodies minimises or eliminates the problem of the antibodies interacting with the host immune system (e.g., the human immune system) when the cells (e.g., neutrophil progenitors and progenies thereof) are infused into the host, particularly when the antibodies are from a different species than the host (for example, when mouse-derived monoclonal antibodies are used to isolate neutrophil progenitors for infusion into a human).

[0072] As compared to using hematopoietic stem and progenitors (HSPCs) as the starting material and expanding neutrophils from these cells, embodiments of the method provide a more efficient way of producing neutrophils as the HSPCs may differentiate and expand into various cell lineages, resulting in lower yield and a longer processing time. The robust supply of neutrophils that may be produced by embodiments of the method may be advantageously harnessed for therapy or research (e.g., in vitro research).

[0073] Neutrophil progenitors may be used for large scale production of neutrophils for therapy (e.g., cell therapy) in, for example, myelo-ablated and neutropenic patients and for research. In various embodiments therefore, there is provided a composition that is enriched in neutrophil progenitors and / or progenies thereof, for example, neutrophil progenitors having at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +. In one embodiment, the composition is enriched in CD71-expressing or CD71hi / + neutrophil progenitors and / or progenies thereof. In various embodiments, the amount / concentration of neutrophil progenitors and / or progenies thereof contained in the enriched composition is higher than the amount / concentration of neutrophil progenitors and / or progenies thereof naturally found in an animal or a human biological sample such as blood and bone marrow. In various embodiments, the composition further comprises one or more components of blood such as red blood cells, white blood cells of various types and platelets. In various embodiments, the composition comprises one derived / obtained from the bone marrow and / or blood (e.g., cord blood, peripheral blood etc.) which is subsequently enriched. In various embodiments, the composition comprises one derived / obtained from human bone marrow and / or human blood.

[0074] In various embodiments, there is provided a composition consisting of neutrophil progenitors and / or progenies thereof, for example, neutrophil progenitors having at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +. In various embodiments, the composition consists of CD71-expressing neutrophil progenitors and / or CD71hi / + neutrophil progenitors and / or progenies thereof. In various embodiments, the composition consists of neutrophils derived from neutrophil progenitors, for example, neutrophil progenitors having at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11blo / − and / or CD49dint / hi / +, or CD71-expressing neutrophil progenitors or CD71hi / + neutrophil progenitors.

[0075] In various embodiments, the composition comprises a therapeutic composition. In various embodiments, there is provided embodiments of the composition for use in therapy. In various embodiments, there is provided embodiments of the composition for use in cell therapy. In various embodiments, there is provided embodiments of the composition for use in treating a condition selected from the group consisting of: a blood disorder, a bone marrow disorder, an immune system disorder, cancer, blood cancer, an infection (e.g., bacterial and / or fungal infections), neutropenia, multiple myeloma, leukemia, lymphomas, aplastic anemia, thalassemia, sickle cell disease, severe combined immune deficiency syndrome and the like. In one embodiment, there is provided embodiments of the composition for use in treating neutropenia.

[0076] In various embodiments, there is provided use of embodiments of the composition in the manufacture of a medicament for treating a condition selected from the group consisting of: a blood disorder, a bone marrow disorder, an immune system disorder, cancer, blood cancer, an infection (e.g., bacterial and / or fungal infections), neutropenia, multiple myeloma, leukemia, lymphomas, aplastic anemia, thalassemia, sickle cell disease, severe combined immune deficiency syndrome and the like. In one embodiment, there is provided use of embodiments of the compositions in the manufacture of a medicament for treating neutropenia.

[0077] In various embodiments, there is provided a method of treating a condition selected from the group consisting of: a blood disorder, a bone marrow disorder, an immune system disorder, cancer, blood cancer, an infection (e.g., bacterial and / or fungal infections), neutropenia, multiple myeloma, leukemia, lymphomas, aplastic anemia, thalassemia, sickle cell disease, severe combined immune deficiency syndrome and the like in a subject, the method comprising administering to the subject embodiments of the composition. In some embodiments, the composition is derived from the subject (for example, prior to enrichment). In some embodiments, the composition is not derived from the subject. In some embodiments, the composition is derived from a donor. In some embodiments, the method comprises a method of treating neutropenia comprising the administration of CD71hi / + or CD71-expressing neutrophil progenitor (proNeus) to neutropenic patients.

[0078] In various embodiments, there is provided use of embodiments of the compositions in the manufacture of a transfusion composition, for example, for treating a condition selected from the group consisting of: a blood disorder, a bone marrow disorder, an immune system disorder, cancer, blood cancer, an infection (e.g., bacterial and / or fungal infections), neutropenia, multiple myeloma, leukemia, lymphomas, aplastic anemia, thalassemia, sickle cell disease, severe combined immune deficiency syndrome and the like. In one embodiment, there is provided use of embodiments of the compositions in the manufacture of a transfusion composition for treating neutropenia.

[0079] In various embodiments, there is provided a method of preparing a transfusion composition or a composition for transplantation e.g., for a subject such as a neutropenic subject, the method comprising: enriching a composition (or a starting composition) for neutrophil progenitors and / or progenies thereof, for example, neutrophil progenitors having at least one of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11lo / − and / or CD49dint / hi / +. In various embodiments, the method comprises enriching the composition (or the starting composition) for CD71-expressing or CD71hi / + neutrophil progenitors and / or progenies thereof. In various embodiments, the composition (or the starting composition) is derived / obtained from the bone marrow and / or blood (e.g., cord blood, peripheral blood etc.). In various embodiments, the composition (or the starting composition) is derived / obtained from human bone marrow and / or blood. The composition (or the starting composition) may be derived / obtained from the subject or a donor. In some embodiments thereof, the method comprises obtaining the composition (or the starting composition) from the subject prior to enrichment.

[0080] In various embodiments, the enriching step comprises contacting the composition (or the staring composition) with one or more agents for detecting the biomarkers, e.g., molecules capable of binding to one or more of the biomarkers as described herein. In various embodiments, the enriching step comprises contacting the composition (or the staring composition) with one or more antibodies against one or more of CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and / or CD49d.

[0081] In various embodiments, there is provided a method of producing mature neutrophils for use in transplantation comprising of the steps: isolating a subset of neutrophil progenitor (proNeus) from human biological samples such as human cord blood and fetal bone marrow comprising the use of CD71 as a selection marker; culturing the isolated neutrophil progenitor population, for example, for three days in serum-free media containing myeloid expansion supplement for expansion.

[0082] In various embodiments, there is provided a method of identifying an agent that is capable of increasing the amount / concentration of neutrophils and / or neutrophil progenitors in a composition or in a subject, the method comprising: determining the amount / concentration of neutrophils and / or neutrophil progenitors in a first sample obtained from the composition or the subject at a first timepoint before the administration / treatment of a candidate agent to the composition or the subject, determining the amount / concentration of neutrophils and / or neutrophil progenitors in a second sample obtained from the composition or the subject at a second timepoint after the administration / treatment of the candidate agent to the composition or the subject, and comparing the amount / concentration of neutrophils and / or neutrophil progenitors in the first sample and second sample. In various embodiments, the method further comprises concluding that the candidate agent is an agent capable of increasing the amount / concentration of neutrophils and / or neutrophil progenitors when the amount / concentration of neutrophils and / or neutrophil progenitors in the second sample is increased relative to the first sample and concluding that the candidate agent is not an agent capable of increasing the amount / concentration of neutrophils and / or neutrophil progenitors when the amount / concentration of neutrophil progenitors in the second sample is not increased relative to the first sample. In various embodiments, determining the amount / concentration of neutrophils and / or neutrophil progenitors in the first and / or second sample comprising determining the amount / concentration of cells having at least one of the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, CD11lo / − and / or CD49dint / hi / +. In various embodiments, determining the amount / concentration of neutrophils and / or neutrophil progenitors in the first and / or second sample comprising determining the amount / concentration of CD71-expressing or CD71hi / + cells.

[0083] In various embodiments, there is provided a kit, optionally a kit for use in a method as described herein, the kit comprising an agent for detecting biomarker, for example, a molecule capable of binding to the biomarker or having affinity for the biomarker. In various embodiments, the kit comprises at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven, or at least about eight molecules capable of binding to at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight of the biomarkers as described herein. In various embodiments, the kit comprises molecule(s) for binding to at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight biomarker(s) selected from the group consisting of: CD71, LOX-1, CD164, CD112, CD18, TACSTD2, CD11b and CD49d. In various embodiments, the kit comprises antibody or a plurality of antibodies for binding to at least about one, at least about two, at least about three, at least about four, at least about five, at least about six, at least about seven or at least about eight biomarker(s) selected from the group consisting of: CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and CD49d.

[0084] In various embodiments, there is provided a method or a product as described herein.BRIEF DESCRIPTION OF FIGURES

[0085] FIG. 1. Single-cell RNA sequencing analysis reveal GMPs as a heterogeneous group of progenitors. (A) Re-analysis of available and annotated single-cell datasets containing mouse BM GMPs. Normalised counts from each dataset were downloaded and analysed using Seurat package. Louvain clustering was performed and annotations were assigned based on key lineage-related genes. (B) Gating strategy containing mouse BM CMPs, Ly6C−GMPs and Ly6C+GMPs. Colored dots represent index-sorted cells used for Smart-Seq2 scRNA-Seq. (C) (top) Sequenced cells in (B) are subjected to Monocle2 trajectory prediction. Cells are aligned according to pseudotime from left to right. Branching points are indicated and (bottom) the description of each lineage is shown. (D) Branchpoint #1 analysis of lineage-related genes and their expression across pseudotime between granulocytes (black line) and monocytes (grey line) (See also FIG. 8D). (E) Branchpoint #2 analysis of lineage-related genes and their expression across pseudotime between neutrophils (black line) and eosinophils (grey line) (See also FIG. 8E). (F) Total transcripts of CMP and GMP subsets, and sorted downstream neutrophil (preNeus) and monocyte (TpMos) precursors, are subjected to a PCA projection. (G) Smart-Seq2 sequenced cells dataset was integrated with the 10× (Tabula Muris) whole mouse BM dataset using Seurat v3. Data integration quality is represented in the overlay plot and (H) respective plots of each dataset indicating cell identities and relative cluster localisations. (See also FIG. 8).

[0086] FIG. 2. InfinityFlow resolves GMP heterogeneity on a proteomic level. (A) InfinityFlow workflow. Whole mouse BM cells were stained with a backbone panel of lineage markers (see methods) to allow separation of each lineage for UMAP generation. Cells are then aliquoted into wells containing PE-conjugated antibodies. Each well information was then recorded by flow cytometry and processed using InfinityFlow pipeline. (B) t-SNE dimensional reduction analysis of 81 GMP-staining markers from InfinityFlow data. Phenograph clustering was performed and clusters are grouped to each myeloid lineage according to known lineage-restricted markers. (C) Analysis of the top discriminating markers for each cluster derived in (B). Black arrows (top) indicate known lineage-specific surface markers indicating GMP subset identity (right). Data is represented as a Z-score based on predicted Log2 mean fluorescence intensity (MFI) from high (dark) to low (light). Importantly, each section of markers (demarcated by a space in between heatmaps) are the highly expressed markers that represent a certain progenitor subset of GMPs. (D) UMAP projection of total mouse BM cells, representing measured cKit expression levels from high (dark) to low (light) log 2MFI. Neu=neutrophil, preNeu=pre-neutrophil, Eo=Eosinophil, T,B=T and B cells, NK=natural killer cells, Mo=monocytes, Baso=Basophil, DC=dendritic cell, cMoP=common monocyte progenitor, GMP=granulocyte-monocyte progenitor. (E) Zoomed-in expression level (Log2MFI) plots of GMP area (dotted box in (D)), representing measured intensities of backbone markers. Expression continuity of CD34 and CD11b expression from GMP to preNeus is shown (highlighted boxes). Cell subset regions are denoted (bottom left), indicating bridge of progenitor cells. (F) Putative markers for GMP subset identification by InfinityFlow. Zoomed-in plots are represented as predicted intensities (Log2MFI) from low (light) to high (dark) levels. (See also FIG. 9)

[0087] FIG. 3. Flow cytometric analysis of BM GMPs reveal a CD106−CD11blo and a CD106+CD11bhi neutrophil progenitor population. (A) Gating and sorting strategy of mouse BM myeloid cell populations. CMP=common myeloid progenitor, cMoP=common monocyte progenitor. (B) Representative micrographs (n=3) of sorted populations indicated in (A). Scale bars=10 um. Grey arrows indicate hollowing. (C) PCA analysis using bulk RNA-seq data from sorted neutrophil and monocytic precursors according to gating strategy in (A). (D-E) Normalised expression comparing the various key monocyte (D) and neutrophil (E) transcription factors. Results are expressed as mean Log2RPKM (n=3)±SD. (F) Heatmap of the top 5% most variable mouse transcription factors among indicated subsets. Known key factors are highlighted in bold. ProNeu-specific genes are highlighted as shown (black box). Data is represented as a Z-Score of expression (Log2RPKM), calculated per gene from high (dark) to low (light) levels. Importantly, the critical differential genes of each lineage are indicated in bold on the right. (See also FIG. 10)

[0088] FIG. 4. Neutrophil development is dependent on two committed proNeu populations. (A) Representative FACS plot of gated proNeu1 and proNeu2 in WT and Cebpe− / − mice. (B) Absolute counts of BM myeloid progenitors from WT and Cebpe− / − mice. Data is expressed as mean±SD (n=5 per group) and is representative of two independent experiments**=p<0.01, ***=p<0.001, ****=p<0.0001 (Student t-test). (C) BM chimeras were made by reconstituting irradiated mice with equal ratios of WT CD45.1+ and Cebpe− / − CD45.2+ cells. The percentage contributions of various hematopoietic cells by WT CD45.1+ or Cebpe− / − CD45.2+ cells are expressed as mean±SD (n=5) and are representative of two independent experiments. ****=p<0.0001 (Student t-test). (D) UMAP analysis of total live BM cells from WT and Cepbe− / − mice. Cells were manually gated and overlaid onto the UMAP plot, representing the localization of each subset on the UMAP space. (E) In vitro stimulation of sorted populations with CSF-1, quantified for F4 / 80+ macrophages at day 3 and 5. Results are represented as mean (n=4-5 per subset)±SD and are representative of three independent experiments. (F) (top) Experimental setup of (bottom) Intra-BM transfer of sorted uGFP+proNeu1, CD45.2+ proNeu2 and ROSAmT / mG RFP+ preNeus into wildtype CD45.1+ recipients. Black dots represent transferred subset after 3 days. Data are representative of five recipient mice from two independent experiments. Mo=monocytes, Eo=eosinophils. (See also FIG. 11)

[0089] FIG. 5. proNeu1 and proNeu2 are functionally distinct progenitors. (A) Heatmap of total ANOVA-corrected variable genes from bulk RNA-Seq transcripts of sorted precursor subsets. Data is represented as a Z-Score, from low (light) to high (dark) expression. Gene clusters (1 to 3) were defined according to hierarchical clustering and exported for (B) gene ontology (GO) enrichment analysis showing the top GO terms (biological process, cellular component and molecular function) using EnrichR. (C) In vitro proliferation assay of sorted populations over 4 days in culture. Results are expressed as mean fold change (n=3 per subset)±SD and are representative of at least three independent experiments. (D) In vitro colony forming potential of sorted populations. Results are expressed as mean (n=3 per subset)±SD and are representative of at least three independent experiments. *=p<0.05 (Student t-test). (E) Percentage of cells in the proliferating S-G2-M phase of the cell cycle denoted by Fucci-S / G2 / M positive cells. Data are representative of two independent experiments. (F) GO enrichment and biofunction enrichment analysis comparison of proNeu1 and proNeu2. Biofunction enrichment analysis was performed with Ingenuity Pathway Analysis (IPA) tool. (G) Volcano plot comparing BM proNeu1 and proNeu2. Selected DEGs corresponding to proNeu1 and proNeu2 function are labelled on the plot. (H) Experimental set-up of mid-grade cecal ligation and puncture (CLP) sepsis kinetics and analysis timepoints. (I) Absolute counts of total bone marrow GMPs (left) and GMP subsets based on Ly6C expression (right) at indicated timepoints. (J) FACS analysis of BM Ly6C+GMP composition at the indicated timepoints. *=p<0.05 (One-way ANOVA). (K) Absolute counts of total BM GMPs (left) and Ly6C+GMP subsets (right) at indicated timepoints. (H-K) Data are expressed as mean (n=4-9 per timepoint)±SD and are representative of two independent experiments. *=p<0.05 (One-way ANOVA). (See also FIG. 12)

[0090] FIG. 6. Skewed specification of GMPs towards neutrophil commitment is directed by G-CSF during emergency granulopoiesis. (A) Transcriptomic comparison between day 3 septic BM Ly6C−GMPs against WT sham control BM Ly6C-GMPs. Selected genes represent various genes critical for the various myeloid lineages. (B) Cytokine analysis of serum from mid-grade septic mice at various timepoints. Data is expressed as mean (n=4-9 per timepoint)±SD from two independent experiments. *=p<0.05, ***=p<0.001, ****=p<0.0001 (One-way ANOVA). (C) Analysis of Ly6C+GMP subsets after G-CSF complex (G-CSFcx) administration. Data are expressed as mean (n=5 per timepoint)±SD and are representative of two independent experiments. *=p<0.05 (One-way ANOVA) (D) Myeloablative treatment experimental plan (left) and (right) analysis of Ly6C+GMP composition with or without G-CSFcx intervention at day 9 of 5′FU treatment. Lines represent absolute counts of total Ly6C+GMPs at the indicated timepoints. (E) Absolute numbers of bone marrow mature neutrophils and blood neutrophils at the indicated timepoints. (D-E) Data are expressed as mean (n=5 per timepoint)±SD and are representative of two independent experiments. **=p<0.01 (One-way ANOVA). (See also FIG. 13)

[0091] FIG. 7. InfinityFlow of human cord blood characterises 2 proNeu subsets. (A) UMAP of total (red blood cell lysed) umbilical cord blood cells. Each cluster is annotated according to their marker profiles. T,B,NK cells were clustered together as their markers were grouped together as lineage exclusion makers. (B) Expression plots of backbone markers denoting the various neutrophil subsets. Results are expressed as scaled fluorescence intensity. (C) InfinityFlow predicted expression levels of putative markers for proNeu identification. Results are expressed as scaled predicted fluorescence intensity from low (light) to high (dark) levels. (D) Gating of proNeus (left) reveals a rare SSCloCD49d+proNeu1 and SSChi CD49dintproNeu2 subset (right). As proNeu1 cells were rare, the FACS plot of proNeu subsets was generated from a concatenation of all LEGENDScreen™ sample files. (E) Histogram plots of fluorescence intensities of proNeu subsets. (F) FACS analysis of neutrophil subsets from cord blood, peripheral blood and fetal bone marrow samples. (G) Taking the top-expressing markers from each subset (MFI>103), a side-by-side comparative heatmap was generated and plotted. Expression is represented as a Z-score of Log2MFIs normalised per marker, from low (light) to high (dark) levels. (See also FIG. 14).

[0092] FIG. 8. GMPs are a heterogeneous group of progenitors including known monocyte progenitors. (A) (top) Gating strategy of MDPs (monocyte-dendritic cell progenitors) (in dark grey) and cMoPs (common monocyte progenitor) (in light grey) according to (Hettinger et al., 2013). (bottom) Back-gating and overlap of each population onto traditionally gated GMPs (granulocyte-monocyte progenitors) is shown. (B) (left) Gating strategy of BM progenitor populations according to (Liu et al., 2019) and (right) overlap of gated population with conventional GMP gating strategy. (C) Sorting strategy of preNeus and TpMo used for single-cell sequencing. (D-E) Branch expression analysis modelling (BEAM) of (D) branchpoint #1 and (E) branchpoint #2 using Monocle2. Gene expression is represented from low (light) to high (dark) levels. (F) Gene expression analysis of neutrophil-related genes in the indicated subsets. (G) mRNA and corresponding protein marker expression level plots of the index-sorted cells.

[0093] FIG. 9. UMAP, with InfinityFlow, reveals the expression continuity of the various BM lineages. (A) Developmental continuity of cell lineages of the various myeloid lineages expression. (B) Unbiased clustering with PhenoGraph of InfinityFlow dataset. Cluster identity is identified using typical lineage markers and is represented in Table 2. (C) UMAP plots of known lineage-restricted markers from low (light) to high (dark) expression levels, indicating each cell type.

[0094] FIG. 10. proNeu2 are CD34loCD11bhi progenitors found outside the GMP phenotype. (A) Localisation of proNeu1 and preNeus in integrated dataset and (B) differential expression profile of clusters indicated. This expression data is only derived from the unintegrated Tabula Muris dataset. (C) GMP gating strategy without CD11b exclusion showing a CD11blo and CD11bhi proNeus. (D) FACS plot of CD115 (CSF-1R) expression down-regulation with increased temperatures during tissue processing. Data is representative of at least three independent experiments. (E) Frequency and absolute counts of neutrophil progenitors in the mouse bone marrow. Data is expressed as mean±SD (n=5) and is representative of three experiments.

[0095] FIG. 11. Neutrophil development is dependent on two committed proNeu populations. (A) UMAP plot of total BM from WT (left) and Cebpe− / − (right) mice indicating the various cell lineages. Cells were manually gated and overlaid onto the UMAP plot to view each population's location and relationship with their adjacent cell types. (B) (top) UMAP expression plots of CD81 and CD106, indicating the localisation of proNeu2. (bottom) UMAP expression heatmap plots of CD115 and SiglecF indicating the atypical granulocyte population in Cebpe− / − BM cells. (C) In vitro stimulation of sorted populations with M-CSF, quantified for Ly6G+ neutrophils at day 3 and 5. Results are represented as mean (n=3 per subset)±SD and are representative of three independent experiments. (D) Intra-BM transfer of sorted uGFP+ Ly6C−GMP, proNeu1 or proNeu2 into wildtype recipients. Results represent progeny of transferred proNeu1 subset after 1 day of transfer. (E) Composition of the progeny of each transferred subset was analyzed and represented in a bar graph. Data is expressed as mean±SD (n=4 per group) from two independent experiments.

[0096] FIG. 12. Characterisation of two functionally distinct proNeu subsets. (A) Genes encoding for granules and (B) ATP metabolic processes among neutrophil precursor subsets are shown as heatmaps, expressed as normalised values (Z-score) from low (light) to high (dark) levels. Importantly, development from proNeu1 to proNeu2 to preNeu is associated with an increase in ATP metabolic processes. (C) Representative colonies of progenitor subsets at the indicated timepoints. Scale bars=50 μm. (D) mRNA and protein expression of various markers among cMoP and neutrophil precursor subsets are shown as heatmaps, expressed as normalised values (Z-score of log2RPKM (for mRNA expression) or MFI (for protein expression)) from low (light) to high (dark) levels. (E) Representative FACS plots of BM Ly6C+GMPs during mid-grade sepsis at the indicated time points. (F) Representative FACS plot showing Csf1r-GFP expression of BM Ly6C+GMPs during sepsis. (G) Subset percentages within Ly6C+GMPs at the indicated timepoints after sepsis onset. Data are expressed as mean (n=3 per timepoint)±SD and are representative of two independent experiments. *=p<0.05 (Student t-test). (H) Frequency of Csf1r-GFP cells three days after mid-grade sepsis onset. Data are expressed as mean (n=3)+SD and are representative of two independent experiments. *=p<0.05 (Student t-test).

[0097] FIG. 13. Skewed specification of GMPs towards neutrophil commitment is directed by G-CSF during emergency granulopoiesis. (A) Pearson correlation of the percentage of cMoPs among Ly6C+GMPs against spleen sizes measured in grams. (B) Cytokine profile of septic mice at the in the indicated timepoints of sepsis onset. Results are expressed as relative concentrations (normalised per analyte) from low (light) to high (dark) levels.

[0098] FIG. 14 (related to FIG. 7). CD71 specifically isolates proNeus from cord blood. (A) Expression plot of CD71 visualised on UMAP of total cord blood cells. Expression is represented as relative fluorescence intensity (predicted). (B) Flow cytometric validation of CD71 as putative marker for proNeu isolation. (C) Spearman rank correlation plots of mouse surface marker MFI against human surface marker MFI. Each dot represents a common surface marker expressed both in mouse and human (n=140).

[0099] FIG. 15. In vitro differentiation capacity of proNeu subsets. Sorted cells of CD34hi (stem and progenitors), proNeu1 and proNeu2 were cultured for three days in serum-free media containing myeloid expansion supplement (Stem Cell Technologies). Cells were then harvested and analysed for mature neutrophil (CD66b+CD16+CD10+) progeny. Data is representative of 4 donor frozen fetal marrow samples.EXAMPLES

[0100] Example embodiments of the disclosure will be better understood and readily apparent to one of ordinary skill in the art from the following discussions and if applicable, in conjunction with the figures. It will be appreciated that the example embodiments are illustrative, and that various modifications may be made without deviating from the scope of the invention. Example embodiments are not necessarily mutually exclusive as some may be combined with one or more embodiments to form new exemplary embodiments.

[0101] The granulocyte-monocyte progenitor (GMP) is a LinnegcKit+CD34hiCD16 / 32hi lineage-primed progeny derived from common myeloid progenitors (CMPs) that forms characteristic granulocyte-macrophage (GM) colonies in culture. GMPs are known for their potential to generate various myeloid progenies such as neutrophils and monocytes. Since GMPs generate both monocytes and neutrophils, their potential raises important questions during circumstances that demand conflicting needs of these two cell subsets.

[0102] In particular, neutrophils are produced in much larger quantities compared to monocytes and their lineage selection requires the repression of monocyte fate with Gfi1. Furthermore, kinetic labelling studies have demonstrated a much longer transit time of neutrophils in the bone marrow compared to monocytes. It thus remains unclear how GMPs adjust their functional output according to different demands, and whether the disparity in transit time between neutrophils and monocytes is due to distinctions between progenitor characteristics downstream or heterogeneity that already exists within GMPs.

[0103] To address these questions, recent advances in single cell transcriptomics have attempted to determine the developmental cell states of each cell, which has led to a discovery of heterogeneity in myeloid lineages and cell fate decisions. Specifically, it has been proposed that GMPs undergo a mixed-lineage state prior to granulocyte and monocyte specification. While these results provided insights into the lineage priming program within the GMP hierarchy, there is a lack of functional validation on how expression or suppression of lineage-affiliated genes will translate into cellular heterogeneity. Furthermore, although lineage heterogeneity within GMPs has been proposed, it is unclear if committed progenitors already exist among these progenitors and how they may behave differently during inflammation.

[0104] An attempt was made to resolve this heterogeneity with Ly6C and CD115 (CSF-1R) being utilized to subset GMPs into Ly6C−GMPs and Ly6C+CD115hi monocyte (MPs) and Ly6C+CD115lo granulocyte progenitors (GPs). However, these markers alone were not sufficient to fully resolve the strict lineage commitment of each progenitor subset, indicating that better markers are required to evaluate the heterogeneity of these progenitors. Particularly, better markers are required for identifying a neutrophil progenitor.

[0105] Neutrophils are important immune cells which provide protection against bacterial and fungal infections. Due to their short lifespan, neutrophils are continuously produced by specialised bone marrow progenitors to meet the daily demand of 100 million cells per day. Neutrophil development begins with long-lived hematopoietic stem cells, which give rise to highly proliferative progenitors that expand in numbers to generate an adequate supply of mature effector neutrophils for immune surveillance and protection against microbial threats. Despite their importance, the identity and characteristics of a committed neutrophil progenitor are yet to be found.

[0106] The inventors have previously reported the identification of neutrophil precursors known as preNeus. While these precursors developed into neutrophils, they were unable to form colonies in vitro, indicating that they are not the true progenitor cells for neutrophils.

[0107] In this disclosure, through a combination of single-cell transcriptomic and proteomic analyses, the inventors successfully identified an early committed progenitor within the GMPs responsible for the strict production of neutrophils, which they have termed as proNeu1. The comprehensive dissection of GMP hierarchy led to the further identification of a previously unknown intermediate proNeu2 population. Similar populations could be detected in human samples.

[0108] The early committed neutrophil progenitor, proNeu1, is already present within the heterogenous population of GMPs. ProNeu1 is shown to give rise to the intermediate progeny proNeu2, which subsequently differentiates into downstream populations. Importantly, it was found that proNeu1 but not proNeu2, expanded extensively and specifically in the early phase of septic inflammation at the expense of monocytic differentiation.

[0109] The two subsets of neutrophil progenitors, proNeu1 and proNeu2, which are responsible for the extensive production of neutrophils in humans, are characterised by distinct protein surface marker expression profiles such as CD71 expression. Based on these surface markers, the inventors were able to isolate these progenitors and demonstrate their development into mature CD16+CD10+ neutrophils in vitro.

[0110] Collectively, the findings complete the neutrophil maturation trajectory roadmap and call for a revision of the classical GMP nomenclature. The disclosure further exemplifies the importance of understanding progenitor identities to study their function in health and disease.ResultsGMPs Contain a Heterogeneous Group of Lineage-Committed Progenitors

[0111] GMPs are known to give rise to granulocytes, such as neutrophils, and monocytes. As such, GMPs were commonly assumed to possess oligo-potent differentiation potential. However, contrary to this assumption, recent studies have suggested that the GMPs are instead, a heterogeneous mixture containing lineage-committed precursors. To resolve these two viewpoints and to provide a comprehensive understanding of the true hematopoietic potential of cells within this population of cells, the inventors investigated the GMP population by performing an analysis with published repositories of single-cell transcriptomic datasets (Giladi et al., 2018; Olsson et al., 2016). By extracting the annotated GMPs (based on Lin−cKit+Sca-1−CD34hiCD16 / 32hi), the inventors performed t-Distributed Stochastic Neighbour Embedding (t-SNE) (Maaten and Hinton, 2008) analysis and confirmed that GMPs contained a mixed population of monocytic, neutrophilic, eosinophilic and basophilic progenitor subsets (FIG. 1A). Notably, in addition to current published literature, the inventors further discovered multiple clusters pertaining to different granulocyte and monocyte lineages based on known lineage restricted genes. These multiple clusters possessed key monocytic genes like Irf8, Ly86 and Csf1r (FIG. 1A), and their gene expression correlated with the presence of common monocytic progenitors (cMoPs), monocyte progenitors (MPs) and monocyte-dendritic progenitors (MDPs) (FIGS. 8A and 8B). The inventors also observed a neutrophil-like cluster containing high expressions of neutrophil elastase (Elane) and ficollin (Fcnb), which are known genes of the neutrophil lineage. These analyses provide further insight into the heterogeneity of progenitors within GMPs and indications of their cell lineage commitment at the transcriptomic level.

[0112] To further look into the various GMP developmental and transitional states leading towards lineage commitment, single-cell RNA-Seq analysis was performed on index-sorted CMPs and total GMPs. The inventors also sorted late precursors, preNeus and TpMos (transitional pre-monocytes), as reference points for neutrophil and monocyte differentiation respectively (FIG. 8C). Back gating of the sorted GMP population showed the presence of Ly6C+ and Ly6C− subsets (FIG. 1B). Monocle (Qiu et al., 2017) was then utilised to order the cells in pseudotime, from CMPs to fully specified progenitors, allowing for the understanding of the various developmental and trajectory states. Monocle then revealed two distinct branchpoints (FIG. 1C). Deeper analysis on these branchpoints showed key fate-determining genes that change over the course of development suggestive of a monocyte-granulocyte at point 1 (FIG. 1D) and a neutrophil-eosinophil determination point at point 2 (FIG. 1E). These analyses revealed an initial down-regulation of monocytic fate-determining genes (Ly86, Csf1r, Irf8), followed by a combinatorial and selective up-regulation of neutrophil-related genes (Gfi1, Rgcc, Vcam1) that are both important for initiating the neutrophil fate (FIGS. 8D and S8E).

[0113] Upon further analysis with Monocle, the inventors noticed the presence of a specified progenitor population at the terminal end state of the neutrophil branchpoint within the Ly6C+ fraction of GMPs (FIG. 1C). These cells possessed the highest expression of known neutrophil-specific genes, such as Gfi1 and S100a8 among others (FIG. 8F). To determine if this population of cells could be putative neutrophil progenitors, these cells were mapped onto a principal component analysis (PCA) of total transcripts and it was discovered that they clustered closer to preNeus along PC2 away from TpMos (FIG. 1F). These putative neutrophil progenitors possessed low levels of CD115 and high levels of Ly6C, both at the mRNA and protein level (FIG. 8G). Furthermore, by performing single-cell data integration (Stuart et al., 2018) with the Tabula Muris™ BM dataset (Schaum et al., 2018), the inventors were able to confirm the cell identities from the dataset (FIG. 1G). Visualisation of the integration revealed a precise mapping of preNeus and TpMos to their respective lineages, while CMPs mapped towards the erythrocytic lineage as well as the dendritic cell lineage (FIG. 1H). Importantly, it was observed that the putative neutrophil progenitors associated with the initial neutrophil branch point, suggesting that this population can be the early progenitors for neutrophil development (FIG. 1H). Taken together, the data suggests a population of putative neutrophil progenitors exist within the GMP and are responsible for the generation of neutrophils.InfinityFlow Resolves GMP Heterogeneity and Identifies Population Discriminating Surface Markers

[0114] Although transcriptomic signatures provide a useful means in determining cell states, they do not confirm a cell's identity or allow further downstream analysis. Therefore, to validate the GMP heterogeneity on a proteomic level, the expression of 261 surface markers (LEGENDScreen™, Biolegend) (Table 1) on total mouse BM cells was evaluated by flow cytometry. The InfinityFlow (Dutertre et al., 2019) pipeline was then used to predict the co-expression of every surface marker tested and this predicted expression information was concatenated into a single analysis file (FIG. 2A). GMPs stained positively for 81 of these markers. The analysis was first restricted to these 81 markers, which were then used to perform a t-SNE analysis on GMPs only. With PhenoGraph (Levine et al., 2015), the inventors could subset GMPs into 10 subpopulations, confirming on a proteomic level that GMPs are a mix of progenitors (FIG. 2B). Using the top discriminating markers for each cluster, the inventors were able to ascertain the identities of the known monocyte (cluster 2, 6 and 7), eosinophil (cluster 5) and basophil (cluster 4) committed progenitors by the expression of lineage-specific surface markers (FIG. 2C) (Arinobu et al., 2005; Hettinger et al., 2013; Iwasaki et al., 2005). Neutrophils, however, lacked lineage-specific markers to allow for a proper characterisation of this dedicated progenitor.

[0115] Therefore, to circumvent this challenge, UMAP analysis of the InfinityFlow dataset was performed to understand the developmental relationships between cell types in the BM based on their protein expression (Becht et al., 2018; McInnes et al., 2018). One major strength of UMAP is that it preserves the continuity of cell subsets, which allow for the identification of rare and / or transitional populations that would be masked in a t-SNE analysis (Becht et al., 2018). The UMAP analysis was expanded to total BM cells which discriminated the various cell lineages within the BM (FIG. 2D), and allowed for the observation of a clear developmental continuum of cells from early cKit+ progenitors to mature cKit− cells of the basophil, eosinophil, monocyte and neutrophil lineages (FIGS. 2D and 9A). Utilising the markers from InfinityFlow, each cell type was identified and annotated through the co-localisation of each marker on the UMAP space (FIG. 9B, Table 1 and 9C). From the UMAP analysis, the inventors observed GMPs (cKit+Sca-1−CD34+CD16 / 32hi) with a gradual upregulation of Ly6C and a subsequent bifurcation into CD115− and CD115+ cells, representing preNeus and cMoPs respectively (FIGS. 2D and 2E). While it is evident that cMoPs are a subset of the GMP, the branch connecting GMPs with preNeus revealed a progressive upregulation of CD11b and downregulation of CD34 expression along the developmental continuity from GMPs (FIG. 2E). This suggests that an early neutrophil progenitor exist within GMPs and extend along the developmental trajectory towards mature neutrophils. Closer inspection revealed several differentially expressed cell surface markers, including CD81, CD49a, CD106 and CD63, which highlight this branch point (FIG. 2F). These markers potentially serve as positive or exclusion markers to isolate and characterize the putative early neutrophil progenitor.Identification of an Early Neutrophil Progenitor within the GMP

[0116] Using the newly identified markers CD81 and CD106, the inventors characterised two phenotypically distinct neutrophil progenitors (termed as proNeus). This included a CD34hiCD106−CD11blo proNeu1 subset and a CD34loCD106+CD11bhi proNeu2 subset (FIG. 3A). This observation is in line with the scRNA-seq data integration, which also unveiled a gap between the mapped neutrophil progenitor and preNeu cells (FIG. 10A), and cells within this gap expressed a continual progression of neutrophilic genes (FIG. 10B). This suggested that an intermediate subset exists within the developmental trajectory of neutrophil development and is absent from the currently defined GMP population. Indeed, proNeu2 escaped the GMP definition, as CD11b+ cells are excluded from the GMPs (FIG. 10C). The inventors also utilized CD81 to exclude cMoPs as this marker allows for the circumvention of the technical concern of CD115 down-regulation during cell preparation (FIG. 10D). Similar to cMoPs, these neutrophil progenitors are rare and they account for 0.05-0.1% of total BM cells (FIG. 10E).

[0117] Morphological analysis revealed an initial hollowing of the nucleus in the proNeu1 stage, which increases in diameter in the proNeu2 stage (FIG. 3B) and subsequent maturation stages. Using the same sorting strategy for neutrophil progenitors in FIG. 3A, the inventors isolated these cells and performed bulk RNA-seq of myeloid progenitors, including Ly6C−GMP, proNeu1, proNeu2, preNeu, cMoP and TpMo, to examine their differentiation and population inter-relationship. PCA analysis revealed a clear separation of the neutrophil and monocytic lineages (FIG. 3C). Deeper analysis of key neutrophilic and monocytic genes revealed similar expression levels of monocytic genes in Ly6C−GMPs and proNeu1 (FIG. 3D). These genes were then upregulated in cMoPs, signifying their commitment to the monocyte fate. Interestingly, the expression level of key neutrophilic gens Gfi1 and Per3 in proNeu1 are also similar in Ly6C−GMPs (FIG. 3E). The inventors further extended the knowledge of myeloid transcriptional regulation by selecting the top 20% variable transcription factors between these progenitor subsets and plotted them on a heatmap. The analysis featured groups of transcription factors solely expressed in cMoPs or Ly6C−GMPs. Specifically, the data also suggests that Jag1 and Sox13 to be exclusive neutrophil lineage-committing factors (FIG. 3F). Jag1, in particular, was shown to be associated with G-CSF-mediated neutrophil differentiation.

[0118] It has been shown that a deficiency in C / EBPs leads to a disruption in neutrophil development. Here, the RNA-Seq analysis showed an upregulation of Cebpe from proNeu1 to proNeu2, suggesting that C / EBPs could be critical for the development of early neutrophil progenitors (FIG. 3E). To test this, the BM of wildtype (WT) and Cebpe− / − mice was analysed. The analysis revealed that C / EBPε is critical for proNeu2 development (FIG. 4A). Together with the loss of proNeu2, an accumulation of cMoPs was also observed, suggesting a block in neutrophil development resulted in a skewed differentiation towards the monocyte fate (FIG. 4B). These observations were further confirmed by generating BM chimeras with CD45.1+ WT and CD45.2+ Cebepe− / − BM cells in a 50:50 ratio. Analysis of these mice BM showed that proNeu2, and downstream populations, were mostly generated from WT CD45.1+ cells (FIG. 4C). This suggests the importance of proNeu2 as a bridging point between proNeu1 and preNeu. UMAP further illustrates this, showing that proNeu2 acts as a bridge between proNeu1 and preNeu development, and the absence of these cells leads to an aberrant differentiation pathway generating atypical granulocytes that are SiglecF+CD115+ (FIGS. 4D and 11B).

[0119] Since proNeu1 s possessed both monocytic and neutrophilic transcription factors (FIGS. 3D and 3E), it was hypothesized that proNeu1s may not be fully specified to neutrophil lineage and could give rise to monocytes depending on lineage cues. To assess the commitment fate of proNeus, the various sorted progenitor populations were cultured with CSF-1, which is known to skew differentiation towards the monocytic lineage. The results showed that both proNeu1 and proNeu2 gave rise to Ly6G+ neutrophils and not macrophages with CSF-1 (FIG. 11C), while both cMoPs and Ly6C−GMPs mostly gave rise to macrophages by day 5 of culture with CSF-1 (FIG. 4E). To further affirm the neutrophil commitment capacity of proNeu1 and proNeu2, the inventors adoptively transferred sorted Ly6C−GMPs, proNeu1s, proNeu2s and tracked their differentiation potential. While Ly6C−GMPs gave rise to both proNeu1s and cMoPs after 1 day, proNeu1 gave rise to proNeu2s and subsequent neutrophil subsets (FIG. 11D). ProNeu2s similarly only specifically gave rise to preNeus and immature Neus (FIG. 11E).

[0120] As these transfer experiments were performed in separate WT recipients, the inventors wanted to assess the differentiation potential of proNeus within the same microenvironment. To do this, the inventors co-transferred sorted and labelled proNeus (1 &2) and preNeus into WT recipients and tracked their development after three days. The results showed that both proNeu1 s and proNeu2s could only give rise to neutrophils with negligible monocytic differentiation potential (FIG. 4F). Moreover, from proNeu1s to preNeus, a step-wise differentiation progression with a sequential upregulation of Ly6G and CXCR2 was observed. Together, the data highlights a programmed neutrophil lineage commitment that exists within the GMP and this begins with proNeu1 s, which exclusively gives rise to downstream neutrophil subsets through a C / EBPε-dependent proNeu2 development.ProNeu1 and proNeu2 are Functionally Distinct Early Neutrophil Progenitor Populations.

[0121] To dissect the functional heterogeneity and progression of these neutrophil progenitors, the transcriptomic signatures from Ly6C−GMPs to preNeus was analyzed. By plotting the top variable genes among each subset, the inventors derived three distinct clusters of genes differentially regulated between each stage of neutrophil development (FIG. 5A). From the heatmap, the inventors observed a sequential increase in granule production (Cluster 1) (FIGS. 5B and 12A) and a concomitant loss of mitochondrial and ribosomal genes (Cluster 3), in line with their progressive acquisition of neutrophil functionality (FIG. 5B and FIG. 12B).

[0122] As CD34 is a known marker for hematopoietic progenitors, it was wondered if progenitor properties are lost in a CD34lo proNeu2 subset. To test this, the proliferative potential of proNeu1 and proNeu2 was evaluated. In vitro cultures showed that, unlike the minimal colony-forming activity of preNeus, both proNeu1 and proNeu2 possessed high proliferative potential (FIG. 5C). Notably, a lower proliferative capacity in proNeu2 compared to proNeu1 was observed, which is further supported by the fewer colonies generated in vitro (FIGS. 5D and 12C). ProNeu1, distinct from proNeu2, possessed enhanced colony forming potential with a cell cycle activity similar to uncommitted Ly6C−GMPs, as shown by the Fucci cell-cycle transgenic reporter line (Sakaue-Sawano et al., 2008) (FIG. 5E). This suggests that proNeu1 possess higher self-renewing properties, which is then exchanged for effector functions in proNeu2. Furthermore, transcriptomic pathway analyses support this decrease in progenitor function of proNeu2, showing an exclusive enrichment in neutrophil effector functions, while proNeu1 are enriched in cellular components and cell survival (FIG. 5F). Collectively, the data shows that proNeu1 and proNeu2 are two distinct progenitor subsets with unique function pertaining to the development of neutrophils. Similar to their surface marker expression, Cd34 was found to be upregulated in proNeu1 while genes encoding CD106 (Vcam1) and CD11b (Itgam) were significantly enriched in proNeu2 (FIG. 5G). These results hence confirm the scRNA-seq and UMAP (FIG. 10A) analysis that proNeu2 is downstream in the neutrophil lineage from proNeu1.

[0123] To understand how these progenitors might play differential roles in inflammatory states, the inventors utilized a model of sepsis and tracked the BM progenitor composition at various timepoints (FIG. 5H). Through the course of infection, the inventors observed an expansion of Ly6C+GMPs but minimal changes in Ly6C-GMP numbers (FIG. 5I). Further analysis of Ly6C+GMPs revealed a skewed differentiation effect towards the neutrophil lineage on day 3, with a specific increase in proNeu1 frequency at the expense of cMoP numbers (FIG. 5J). Unlike proNeu1, proNeu2 remained largely unchanged during the course of infection, suggesting differential roles for each progenitor during sepsis. The inventors also showed that this skewing effect can be observed from day 1 of sepsis onset (FIGS. 12E and 12G), and confirmed that CD115 was not down-regulated during inflammation using a Csf1r-GFP MaFIA transgenic mouse (FIGS. 12F and 12H). The shift in myeloid progenitor potential then returns to physiological frequencies by day 9, together with a specific expansion of cMoPs (FIG. 5K), suggesting their importance during the resolution phase of sepsis. Importantly, this critical information would have been lost if total GMPs were analysed, exemplifying the need for the analysis of specific progenitor subsets to understand the dynamics of progenitor function in inflammatory conditions.G-CSF-Mediated BM Skewing of Myeloid Progenitors can Modulate Neutrophil Expansion

[0124] The ability of BM progenitors to replenish the circulating pool of immune cells is a critical step in infections and diseases when a large demand of mature cells is needed. In particular, neutralization of invading pathogens and microbial insults requires emergency granulopoiesis, which is a mechanism whereby the immune system adapts to produce and mobilize neutrophils in a prompt and efficient manner.

[0125] To determine if the increased proNeu1 frequencies during sepsis are pre-determined in early progenitors, transcriptomic analysis of Ly6C−GMPs was performed at day 3 of sepsis onset, revealing a down-regulation of multiple lineage associated genes, such as Mcpt8, Ly86, Prss34 and Fcera1. An up-regulation of granule protein genes such as S100a9, S100a8, Chil3 and Lcn2 was also observed (FIG. 6A). These results not only verify the importance of the proNeu findings, but further confirms the skewing effect of proNeu1 differentiation. Interestingly, at day 6 where variability of BM skewing is at its peak, the inventors observed a correlation of spleen size with the recovery of the skewed progenitor compartment (FIG. 13A), indicating a possible role of extra-medullary haematopoiesis in the resolution of sepsis.

[0126] To determine the factors and signals that enabled the expansion of proNeu1 and proNeu2, the inventors performed a screen of inflammatory analytes on mice serum at the various time points (FIG. 13B). Specifically, high levels of G-CSF and IL-6 were found at day 3, which may account for the skewed neutrophil potential (FIG. 6B). This is supported by a significant increase in proNeu frequencies through in vivo administration of G-CSF (FIG. 6C). To demonstrate this instructive skewing effect, myelo-ablated mice BM cells were analysed using a chemotherapeutic drug 5-Fluorouracil, and G-CSF was introduced during the recovery of the myeloid compartment. Introduction of G-CSF at day 9 showed a marked increase in proNeu1 frequency at day 12 after myeloablation (FIG. 6D), and this translated into much higher neutrophil production on day 15 (FIG. 6E). Taken together, the data highlights the relevance of the proNeu findings by providing a framework to understand the biology of sepsis through the comprehension of progenitor skewing. Notably, the results support the G-CSF-mediated skewing effect of proNeu commitment in the early phase of the sepsis inflammatory phase, which is subsequently compensated by high monocyte production and commitment for effective resolution of sepsis.InfinityFlow of Human Cord Blood Cells Reveal a proNeu1 and a proNeu2 Subset

[0127] To determine if such progenitors exist in human, the same workflow (i.e., the InfinityFlow pipeline) was applied to examine whole human cord blood cells to screen for differential surface markers that can help identify these progenitor cells.

[0128] Briefly, Red blood cells (RBC)-lysed cord blood cells are stained with a common backbone panel of surface markers that denote the various cell lineages present in the cord blood. Thereafter, cells are aliquoted into wells, each containing a unique PE-conjugated surface marker (LEGENDScreen™). Samples are acquired and the expression profiles of each PE marker was processed with InfinityFlow, a machine learning application that predicts the co-expression profile of each marker with every tested marker. This allowed for the discovery of new subsets with high dimensional phenotypic characterisation.

[0129] UMAP analysis of total cord blood cells showed distinct populations representing the various lineages (FIG. 7A). Deeper analysis into the neutrophil cluster revealed the previously identified three bone marrow neutrophil subsets, with similar protein expression profiles as described in mouse. Importantly, through UMAP, a putative proNeu population possessing low expression levels of CD11b and high levels of CD49d was identified (FIG. 7B). Mining on the InfinityFlow dataset, the inventors further identified several potential markers for human proNeu identification. These included CD71, LOX-1, CD164, CD112, CD181 and TACSTD2 (FIG. 7C). Validation of one of these markers, CD71, showed that it was exclusively expressed by proNeus among total RBC-lysed cord blood cells (FIG. 14A). This suggests a possible isolation strategy of proNeus (FIG. 14B). This strategy is an easy 2-step process, which utilizes large volumes of donor cord blood commonly available for clinical use. These cells are typically discarded after enrichment for CD34+ stem and progenitor cells which are used for cell therapeutic purposes.

[0130] The inventors could further subset proNeus into proNeu1 and proNeu2 by their CD49d expression level and side-scatter properties (FIG. 7D). CD49dhiSSClo proNeu1 were rare cells as compared to CD49dintSSChi proNeu2, and they expressed higher levels of CD34, CD38 and CD81 (FIG. 7E). The expression of CD34 and CD38 suggests that proNeu1 cells exist within the human GMP nomenclature of Lin-CD34+CD38+CD45RA+ cells. To validate the findings, cord and adult peripheral blood, as well as fetal bone marrow samples were analysed. From the analysis, the inventors were able detect proNeu1 and proNeu2 in cord blood donor samples but not in the peripheral blood. In the fetal bone marrow, the inventors could detect a higher frequency of proNeu1, along with higher frequencies of proNeu2, preNeus and immature Neus (FIG. 7F).

[0131] The data suggest a similarity in neutrophil development between mouse and human with the identification of human equivalents of proNeu1 and proNeu2. To further show this correlation, the inventors utilized and compared the protein expression profiles of each neutrophil subset from both the mouse and human InfinityFlow datasets. The MFIs were extracted from each subset and it was observed that each subset had moderate correlation between the mouse and human equivalent neutrophil subset (FIG. 14C). Moreover, by comparing the top-expressing markers of each subset in both mouse and human, 16 markers that share similar expression progression from proNeu1 to mature neutrophils were identified (FIG. 7G). This further suggests a similar acquisition of function and maturation in both mice and human. Taken together, the data provides a complete analysis of the human neutrophil pathway, identifying the human equivalents of proNeu1 and proNeu2 with their associated surface marker expression profiles.

[0132] Finally, to show that the identified progenitors proNeu1 and proNeu2 have the potential to generate mature neutrophils, in vitro cultures of sorted proNeu1 and proNeu2 cells were performed. The data showed that both proNeu1 and proNeu2 were capable of generating CD16+CD10+ mature neutrophils (FIG. 15). This generation takes 3 days, which provides a quick supply of neutrophils if transferred into patients who undergo myeloablative treatments. This is observed in the CD34hi cultured cells, which generate very low numbers of mature neutrophils after 3 days of culture. This finding also allows for the further development of culture conditions that will allow for the extended proliferation and expansion of donor neutrophils for therapeutic purposes. Taken together, the data strongly supports the existence of two distinct neutrophil progenitors and the method to isolate these cells for therapeutic uses.Discussion

[0133] The classical model of haematopoiesis is a hierarchical and step-wise differentiation program, led by instructive transcription factors that govern each cell's lineage fate. The generation of myeloid cells are through GMPs (Lin−cKit+Sca-1−CD34+CD16 / 32hi) as shown by the formation of both granulocytic and monocytic colonies in methylcellulose colony-forming assays (Akashi et al., 2000). Yet, whether GMPs are a bona fide homogenously multipotent subset or a heterogenous blend of lineage-restricted populations remains a long-standing question. To gain better insights into this, the inventors employed a combinatorial approach of transcriptomic, proteomic and bioinformatic tools to develop a phenotyping scheme for identifying putative progenitors within the GMP populations. By subjecting the currently defined GMPs through optimized subset-defining surface markers derived from InfinityFlow (Dutertre et al., 2019) and bioinformatic approaches, the inventors identified a population of neutrophil-committed progenitors (i.e. CD81+CD106−proNeu1) that exist within GMP population. Furthermore, with deep surface marker phenotyping and RNA-Seq profiling, the inventors further characterized a downstream CD81+CD106+proNeu2 progenitor subset. Together, these data serve as a missing link in the early stages of the neutrophil developmental pathway, which allows for the mapping of their development from proNeu1→proNeu2→preNeu→immature neutrophil→mature neutrophil.

[0134] The ability to delineate early neutrophil progenitors from GMPs allows for the assessment of transcription factors that are involved in instructing myeloid progenitor lineage specification and commitment. Inspection of a list of TFs (Irf8, KIf4, Irf5, Gfi1, Cebpe and Per3) that are known to govern monocytic and granulocytic lineage commitment consistently showed that Ly6C−GMPs and proNeu1 express similar levels of these TFs, while differential expression of these TFs only became evident at the proNeu2 and cMoP stage. This indicates that a neutrophil-monocyte lineage bifurcation may occur at this hierarchical level. This raises the question about the extent of lineage commitment by proNeu1 population, i.e., whether this subset of progenitor is specified or committed towards the neutrophil lineage. The in vitro and in vivo functional studies revealed that proNeu1 is committed to the neutrophil lineage, as proNeu1 can only give rise to neutrophils even when they were cultured with a strong monocytic lineage promoting cytokine such as M-CSF. Additionally, the RNA-Seq data showed that cMoP, Ly6C−GMP, proNeu1 and proNeu2 possess distinct “TF signatures”, providing an overview of putative TFs that could be important for lineage specification and commitment of these progenitors. For instance, the inventors observed increased levels of Jag1 and Sox13 expression specifically only in proNeu1, suggesting that these two TFs can be developed as markers for tagging proNeu1 and to be examined as key regulators for proNeu1 differentiation. Collectively, the data not only confirmed previous lineage-associated TFs, but also extended the list of putative TFs for myeloid lineage specification and commitment.

[0135] A previous in vivo tracking study demonstrated that granulocytes and monocytes are closely related in terms of their clonal origin. Here, the disclosure describes a transcriptionally and molecularly defined neutrophil progenitor in the GMP hierarchy, allowing for a better understanding of the lineage relationships and the dynamics of neutrophil / monocyte production. Given that myeloid progenitors can be sustained without the input from HSCs, it is conceivable that these progenitors are highly adaptable to varying inflammatory perturbations, according to the demands of the immune response. The study revealed that there is a selective expansion of proNeu1 and disappearance of cMoP during the acute phase of sepsis onset. This phenomenon could be a consequence of skewed differentiation potential of progenitor cells, conceivably at the Ly6C-GMP level, and a preferential proliferation of early neutrophil progenitors to meet the immediate requirements for neutrophils.

[0136] In summary, the disclosure provides new insight into the divergent pathways of myeloid progenitor development towards neutrophils and monocytes from GMPs, and how the balance between neutrophil / monocyte production is important for host homeostasis. Moreover, the identification of early neutrophil progenitors opens up new avenues for therapeutic strategy for the management of neutropenia in hematopoietic stem cell transplantation or high dose chemotherapy, by the infusion of an expanded proNeu subset. This can serve a source for rapid neutrophil repopulation to help confer protection against infection during this critical period of need.Materials and MethodsMice

[0137] Eight to twelve-week-old C57BL / 6 mice were bred and maintained under specific pathogen-free (SPF) conditions in the Biological Resource Centre (BRC) of A*STAR, Singapore. Both males and females were used for experiments, but animals were sex- and age-matched in each experiment as much as possible. uGFP (C57BL / 6-Tg(UBC-GFP)30Scha / J), CD45.1 (B6.SJL-Ptprca Pepcb / BoyJ), MaFIA (C57BL / 6-Tg(Csf1 r-EGFP-NGFR / FKBP1A / TNFRSF6)2Bck / J) and Rosa26mT / mG (STOCK Gt(ROSA)26sotm4(AcTB-tdTomato,-EGFP)Luo / J mice were obtained from The Jackson Laboratory. Fucci-S / G2 / M (#474) were obtained from the RIKEN BioResource Center (Ibaraki, Japan; (Tomura et al., 2013)). Cebpe− / − provided by P. Koeffler (Cancer Science Institute of Singapore, NUS, Singapore) (Yamanaka et al., 1997). All transgenic mice were maintained on a C57BL / 6 background and experiments were performed under the approval of the Institutional Animal Care and Use Committee (IACUC), in accordance with the guidelines of the Agri-Food and Veterinary Authority (AVA) and the National Advisory Committee for Laboratory Animal Research (NACLAR) of Singapore.Human Blood, Cord Blood and Fetal Bone Marrow

[0138] All samples were obtained in accordance with a favorable ethical opinion from SingHealth CIRB or A*STAR, the Singapore Immunology Network. Fresh (<24 hours from collection) human umbilical cord blood (UCB) units were collected through a collaboration with National Cancer Centre Singapore (NCCS). NCCS obtained the UCB units through Singapore Cord Blood Bank (SCBB), from research consented units failing to meet the criteria for public clinical banking. Usage of the samples were approved by the Centralized Institutional Review Board (CIRB) of Singapore Health Services (that covers NCCS) as well as the dedicated Research Advisory Ethics Committee of SCBB.Treatments

[0139] For 5-Fluorouracil (5-FU) myeloablative treatment, mice were injected once intraperitoneally with 150 mg / kg 5-FU (Sigma-Aldrich) or PBS control. For G-CSF treatment, mice were injected once intraperitoneally with 1.5 μg of G-CSF / anti-G-CSF antibody complex (G-CSFcx) as previously described (Rubinstein et al., 2013). Briefly, G-CSFcx were generated by incubating G-CSF (Neupogen) and anti-G-CSF (BVD11-37G10; Southern-Biotech) at 1:5 cytokine to antibody ratio for 20 min at 37° C., and were next diluted at least 10-fold in PBS before injection.Tissue Preparation and Data Analysis for Flow Cytometry and Cell Sorting

[0140] Blood was obtained via an incision in the submandibular region and was then lysed in red blood cell lysis buffer (eBioscience). For BM cells, mice femurs were flushed using a 23-gauge needle in PBS containing 2 mM EDTA and 2% fetal bovine serum (FBS) and passed through a 70-μm nylon mesh sieve. Spleens were harvested and homogenized into single-cell suspensions using 70-μm nylon mesh sieves and syringe plungers. Antibodies were purchased from BD, Biolegend, eBioscience or R&D. For the identification of BM myeloid progenitor cell subsets, cells were stained with fluorophore-conjugated anti-mouse antibodies against CD34 (RAM34), CD11b (M1 / 70), CD16 / 32 (2.4G2), CD115 (AFS598), cKit (2B8), CXCR2 (SA044G4), CXCR4 (2B111), Gr1 (RB6-8C5), Ly6C (HK1.4) CD106 (429), CD81 (Eat-2), and Flt3 (A2F10), together with exclusion lineage markers that include Ly6G (1A8), CD90.2 (53-2.1), B220 (RA3-6B2), NK.1.1 (PK136), and Sca-1 (D7). After exclusion of cell doublets and dead cells with DAPI, proNeu1 were identified as (Lin / CD115 / Flt3)-cKithiCD16 / 32hiLy6C+ CD34hiCD11bloCD106−, proNeu2 were identified as (Lin / CD115 / Flt3)−cKithiCD16 / 32hiLy6C+ CD34hiCD11bhiCD106+, preNeus were identified as (Lin / CD115 / Siglec-F)−Gr1+CD11b+CXCR4h ickitintCXCR2−, CMPs were identified as Lin−cKit+Sca-1−CD16 / 32intCD34int, Ly6C−GMPs were identified as Lin−cKit+Sca-1−CD16 / 32hiCD34hi, MDPs were identified as Lin−cKit+Sca-1−CD115+Flt3+Ly6C− or and cMoPs were identified as Lin−cKit+Sca-1−CD115+CD81−Flt3−Ly6C+. Flow cytometry acquisition was performed on a 5-laser BD LSR II (BD) using FACSDiva software, and data was subsequently analyzed with FlowJo software (Tree Star). Cell numbers were quantified with count beads (CountBright; Life Technologies) according to the manufacturer's instructions. Sorting of BM neutrophil subsets were performed using a BD ARIAII (BD) to achieve >98% purity.LEGENDScreen™ and InfinityFlow Pipeline

[0141] Mice femurs, tibias, pelvic bones, humeri and spinal bone marrow were harvested and crushed in PBS containing 2 mM EDTA and 2% foetal bovine serum (FBS) and passed through a 70-μm nylon mesh sieve. For human cord blood, RBC lysis was performed on one unit of cord blood donor sample for 10 min at room temperature. Cells were spun down at 400 g for 10 min. This process was repeated once to remove most RBC cells. Mouse cells were first stained with fixable live / dead for 30 min before staining with a backbone panel cocktail of mouse antibodies to define the various lineages in the BM. These markers include: CD34 (RAM34), CD11b (M1 / 70), CD16 / 32 (2.4G2), CD115 (AFS598), cKit (2B8), CXCR2 (SA044G4), Ly6C (HK1.4), Flt3 (A2F10), Sca-1 (D7). CD48 (HM48-1), CD43 (S11), CD62L (MEL-14) and FITC-conjugated lineage markers (Ly6G (1A8), CD90.2 (53-2.1), B220 (RA3-6B2), NK.1.1 (PK136)). After 90 min of staining at 4° C., cells were lysed in 1×RBC lysis (eBioscience) for 5 min, then spun down at 400 g for 5 min. Cells were then stained with secondary streptavidin for 30 min and washed as before. To enrich the BM for progenitor identification, mature neutrophils, B, T and NK cells were partially depleted using FITC selection kit (Stem Cell Technologies) according to the manufacturer protocol. For cord blood cells, cells were stained with a backbone panel of antibodies for 30 min at 4° C., including: CD3 (UCHT1), CD56 (HCD56), CD19 (HIB19), CD10 (H110a), CD49d (9F10), CD34 (581), CD66b (G10F5), cKit (104D2), CD38 (HIT2), CD15 (H198), CD14 (M5E2), CD101 (BB27), CD45 (H130), CD11b (ICRF44), CD16 (3G8). Cells were then counted and aliquoted into individual wells containing specific PE-conjugated marker. (Tables 1 and 3). After staining for 30 min, plates were washed and fixed before FACS acquisition was performed on a 5-laser BD LSR II (BD) using FACSDiva software, and data was subsequently processed through the InfinityFlow pipeline as described elsewhere (Dutertre et al., 2019).Cytospin and Wright-Giemsa Staining

[0142] Sorted neutrophil subsets (5×104 cells each) were spun onto glass slides using Cytospin 4 Cytocentrifuge (Thermo scientific), dried for 10 minutes, fixed in methanol and stained with the Hema 3 manual staining system (Fisher Diagnostics) according to the manufacturer's protocol. Images were acquired with an Olympus BX43 equipped with a 100× oil immersion objected, and image brightness was adjusted with Photoshop (Adobe).Transcriptomics

[0143] For single-cell transcriptomic analysis, BM CMPs, GMPs, preNeus and TpMos cells were sorted based on the gating strategy depicted in FIGS. 1B and 8C. Single cell cDNA libraries were using the SMARTSeq v2 protocol (Picelli et al., 2014) with the following modifications: 1. 1 mg / ml BSA Lysis buffer (Ambion® Thermo Fisher Scientific, Waltham, Mass., USA); 2. Use of 200 pg cDNA with 1 / 5 reaction of Illumina Nextera XT kit (Illumina, San Diego, CA, USA). The length distribution of the cDNA libraries was monitored using a DNA High Sensitivity Reagent Kit on the Perkin Elmer Labchip (Perkin Elmer, Waltham, MA, USA). All samples were subjected to an indexed paired-end sequencing run of 2×151 cycles on an Illumina HiSeq 4000 system (Illumina, San Diego, CA, USA) (250 samples / lane).

[0144] For total-mRNA bulk RNA-seq analysis, BM Ly6C-GMP, proNeu1, proNeu2 and cMoP were sorted based on the gating strategy of FIG. 4A. preNeus were sorted as described previously. Total RNA was extracted using Arcturus PicoPure RNA Isolation kit (Applied Biosystems™ Thermo Fisher Scientific) according to manufacturer's protocol. All human RNAs were analyzed on Agilent Bioanalyser for quality assessment with a median RNA Integrity Number (RIN) of 9.4. cDNA libraries were prepared using 2 ng of total RNA with 1 ul of 1:50,000 dilution of ERCC RNA Spike in Controls respectively (Ambion® Thermo Fisher Scientific) using the SMARTSeq v2 protocol (Picelli et al., 2014) with the following modifications: 1. Addition of 20 μM TSO; 2. Use of 200pg cDNA with 1 / 5 reaction of Illumina Nextera XT kit (Illumina, San Diego, CA, USA). The length distribution of the cDNA libraries was monitored using a DNA High Sensitivity Reagent Kit on the Perkin Elmer Labchip (Perkin Elmer, Waltham, MA, USA). All samples were subjected to an indexed paired-end sequencing run of 2×151 cycles on an Illumina HiSeq 4000 system (Illumina) (26 samples / lane). Raw reads were aligned to mouse genome build GRCm38 using STAR aligner. Read counts per gene were then calculated using the featureCounts (part of the Subread package) based on GENCODE gene annotation version M20. Log 2 transformed reads per kilobase per million mapped reads (log 2 RPKM) normalization was done to account for transcript length and the total number of reads. Differentially expressed genes (DEGs) analysis was done using edgeR (Robinson et al., 2009) on protein coding genes only. DEGs with FDR (False Discovery Rate) less than 0.05 were selected as statistically significant.In Vitro Cell Culture

[0145] Sorted cells (1×104 for each subset) were plated onto 96-well plates in triplicates and cultured at 37° C., 5% CO2 in StemSpan™ SFEM II (Stem Cell Technologies) containing penicillin (100 U / ml), streptomycin (100 ug / ml), a combination of cytokines (50 ng / ml SCF, 10 ng / ml LIF, 20 ng / ml IL-3, 20 ng / ml IL-6) and with or without 50 ng / ml CSF-1. For human fetal marrow cultures, frozen samples were thawed and sorted before plating in 96-well plates in StemSpan™ SFEM II containing penicillin (100 U / ml), streptomycin (100 ug / ml) and StemSpan™ myeloid expansion supplement (Stem Cell Technologies). For colony assays, sorted cells (3×104) were cultured for in Iscove's modified Dulbecco's medium (Sigma) with 25 mM HEPES and L-Glutamine (Chemtron) containing 10% (vol / vol) FBS, 1 mM sodium pyruvate, penicillin (100 U / ml) and streptomycin (100 ug / ml), 1% (wt / vol) methylcellulose (MethoCult M3234, Stem Cell Technologies) and the same cytokine combination as above. Representative colony images were collected with an Olympus IX-81 microscope (Olympus). Image brightness was adjusted with Photoshop.Adoptive Cell Transfer

[0146] Sorted uGFP+ proNeu1, RFP+ (Rosa26mT / mG) proNeu2 and CD45.1 preNeus (5×104 cells each) were transferred intra-BM into wildtype recipients as described previously (Chong et al., 2016). Briefly, recipient mice were anesthetized with ketamine (150 mg / kg) / xylazine (10 mg / kg), and had their right leg shaved to expose the kneecap. Sorted proNeu1, proNeu2 and preNeus were mixed and resuspended in 1×PBS in equal proportions and a volume of 10 μL was administered into the tibia through the kneecap using a 29-gauge insulin needle. For single population transfers, sorted uGFP+Ly6C-GMP, proNeu1 and proNeu2 (5×104 cells) were used. After 24 hr or 72 hours after cell transfer, tibias were collected, stained and analyzed by flow cytometry.CLP-Induced Sepsis

[0147] Cecal ligation and puncture was performed as described previously (Rittirsch et al., 2009). Briefly, the peritoneal cavity was exposed under ketamine / xylazine anesthesia and the cecum was exteriorized. 50% (mid-grade) or 80% (high-grade) of the cecum was ligated distal of the ileo-cecal valve using a non-absorbable 7-0 suture. A 26-gauge needle was used to perforate the distal end of the cecum, and a small drop of feces was extruded through the puncture before being relocated into the peritoneal cavity. The peritoneum was closed and mice were subsequently treated with saline and Buprenorphine (5-20 mg / kg) by subcutaneous injection. For sham-operated controls, the peritoneum was exposed and the cecum was exteriorized before closing the peritoneum as mentioned above. Mice were euthanized and harvested 2 weeks after the surgery.Quantification and Statistical Analysis

[0148] Statistical analyses were done using Prism software (Graphpad). Student's t-test or one-way analysis of variance (ANOVA) with Bonferroni correction were performed.Tables

[0149] TABLE 1(Related to FIG. 2) List of surface markerstested in mouse BM LEGENDScreen ™CloneLocationMarker(Biolegend)IsotypePlate_1_A1_013BlankPlate_1_A10_022CD1032E7Armenian Hamster IgGPlate_1_A11_023Delta_like 4HMD4-1Armenian Hamster IgGPlate_1_A12_024CD195HM-CCR5Armenian Hamster IgGPlate_1_A2_014Isotype_AHIgGHTK888Plate_1_A3_015CD3e145-2C11Armenian Hamster IgGPlate_1_A4_016CD8016-10A1Armenian Hamster IgGPlate_1_A5_017CD81Eat-2Armenian Hamster IgGPlate_1_A6_018CD154MR1Armenian Hamster IgGPlate_1_A7_019Notch 1HMN1-12Armenian Hamster IgGPlate_1_A8_020CD30mCD30.1Armenian Hamster IgGPlate_1_A9_021CD178MFL3Armenian Hamster IgGPlate_1_B1_025Notch 4HMN4-14Armenian Hamster IgGPlate_1_B10_034CD11cN418Armenian Hamster IgGPlate_1_B11_035Delta_like 1HMD1-3Armenian Hamster IgGPlate_1_B12_036CD19629-2L17Armenian Hamster IgGPlate_1_B2_026CD229Ly9ab3Armenian Hamster IgGPlate_1_B3_027CD69H1.2F3Armenian Hamster IgGPlate_1_B4_028Notch 3HMN3-133Armenian Hamster IgGPlate_1_B5_029JAML4E10Armenian Hamster IgGPlate_1_B6_030Notch 2HMN2-35Armenian Hamster IgGPlate_1_B7_031CD1942G12Armenian Hamster IgGPlate_1_B8_032CD152UC10-4B9Armenian Hamster IgGPlate_1_B9_033CD120a55R-286Armenian Hamster IgGPlate_1_C1_037CD29HMβ1-1Armenian Hamster IgGPlate_1_C10_046CD16.2mDcR2-1Armenian Hamster IgGPlate_1_C11_047CD36HM36Armenian Hamster IgGPlate_1_C12_048DcTRAIL_R1mDcR1-3Armenian Hamster IgGPlate_1_C2_038CD55RIKO-3Armenian Hamster IgGPlate_1_C3_039Jagged 2HMJ2-1Armenian Hamster IgGPlate_1_C4_040CD79bHM79-12Armenian Hamster IgGPlate_1_C5_041IFNgR b chainMAR1-5A3Mouse IgG1, kPlate_1_C6_042CD612C9.G2Armenian Hamster IgG(HMβ3-1)Plate_1_C7_043CD121aJAMA-147Armenian Hamster IgGPlate_1_C8_044TCRb chainGL3Hamster IgGPlate_1_C9_045FceRIaMAR-1Armenian Hamster IgGPlate_1_D1_049CD84mCD84.7Armenian Hamster IgGPlate_1_D10_058CD339HMJ1-29Armenian Hamster IgGPlate_1_D11_059CD49aHMa1Armenian Hamster IgGPlate_1_D12_060PD1HMH5AArmenian Hamster IgGPlate_1_D2_050CD48HM48-1Armenian Hamster IgGPlate_1_D3_051CD49bHMa2Armenian Hamster IgGPlate_1_D4_052CD120bTR75-89Armenian Hamster IgGPlate_1_D5_053CD183CXCR3-173Armenian Hamster IgGPlate_1_D6_054CD262MD5-1Armenian Hamster IgGPlate_1_D7_055HVEMHMHV-1B18Armenian Hamster IgGPlate_1_D8_056TCR Vd1.1_1.2H57-597Armenian Hamster IgGPlate_1_D9_057B7H4HMH4-5G1Armenian Hamster IgGPlate_1_E1_061CD85kH1.1Armenian Hamster IgGPlate_1_E10_070Ly108330-AJMouse IgG2a, kPlate_1_E11_071CD2074C7Mouse IgG2a, kPlate_1_E12_072CX3CR1SA011F11Mouse IgG2a, kPlate_1_E2_062Plexin B23E7Armenian Hamster IgGPlate_1_E3_063CD27LG.3A10Armenian Hamster IgG1,Plate_1_E4_064DR34C12Armenian Hamster IgG1Plate_1_E5_065TCR gd4B2.9Armenian Hamster IgGPlate_1_E6_066Isotype_mIgG2aMOPC-173Mouse IgG2a, kPlate_1_E7_067CD45.1A20Mouse (A.SW) IgG2a, kPlate_1_E8_068CD45.2104Mouse (SJL) IgG2a, kPlate_1_E9_069NK1.1PK136Mouse IgG2a, kPlate_1_F1_073Isotype_mIgG1MOPC-21Mouse IgG1, kPlate_1_F10_082Trem_like 416E5Mouse IgG1, kPlate_1_F11_083CD59amCD59.3Mouse IgG1, kPlate_1_F12_084Ly49H3D10Mouse IgG1, kPlate_1_F2_074CD66aMAb-CC1Mouse IgG1, kPlate_1_F3_075IFNAR1MOB-47Armenian Hamster IgGPlate_1_F4_076Tim2F37-2C4Mouse IgG1, kPlate_1_F5_077CD2728F4Mouse IgG1, kPlate_1_F6_078CD64X54-5 / 7.1Mouse IgG1, kPlate_1_F7_079CD351TX61Mouse IgG1, kPlate_1_F8_080LAPTW7-20B9Mouse IgG1, kPlate_1_F9_081TIGIT1G9Mouse IgG1, kPlate_1_G1_085CD90.1OX-7Mouse IgG1, kPlate_1_G10_094Siglec H551Rat IgG1, KPlate_1_G11_095CD255MTW-1Rat IgG1, kPlate_1_G12_096CD202bTEK4Rat IgG1, kPlate_1_G2_086Isotype_mIgG2bMPC-11Mouse IgG2b, kPlate_1_G3_087CD157BP-3Mouse IgG2b, kPlate_1_G4_088CD159a16A11Mouse IgG2b, kPlate_1_G5_089XCR1ZETMouse IgG2b, kPlate_1_G6_090Isotype_mIgMMM-30Mouse IgM, kPlate_1_G7_091SSEA_1MC-480Mouse IgM, kPlate_1_G8_092Isotype_rIgG1RTK 2071Rat IgG1, kPlate_1_G9_093Ig light chain κRMK-45Rat IgGPlate_1_H1_097GITR LigandYGL 386Rat IgG1, kPlate_1_H10_106Mac3M3 / 84Rat IgG1, kPlate_1_H11_107CD223C9B7WRat IgG1, kPlate_1_H12_109CD134OX-86Rat IgG1, kPlate_1_H2_098CD147OX-114Rat IgG1, kPlate_1_H3_099CD73TY / 11.8Rat IgG1, kPlate_1_H4_100CD51RMV-7Rat IgG1, kPlate_1_H5_101NKG2DCX5Rat IgG1, kPlate_1_H6_102CD963.3Rat IgG1, kPlate_1_H7_103Integrin b7FIB27Rat IgG1, kPlate_1_H8_104CD2101B1.3aRat IgG1, kPlate_1_H9_105CD83Michel-19Rat IgG1, kPlate_2_A12_119Isotype_rIgG2aRTK2758Rat IgG2a, kPlate_2_A2_111CD41MWReg30Rat IgG1, kPlate_2_A3_112CD2687H22-E16Rat IgG1, kPlate_2_A4_113CD144BV13Rat IgG1, kPlate_2_A5_114CD3707H11Rat IgG1, kPlate_2_A6_115CD369RH1Rat IgG1, kPlate_2_A7_116PIR A / B6C1Rat IgG1, kPlate_2_A8_117CD22OX-97Rat IgG1, kPlate_2_A9_118E_CadherinDECMA-1Rat IgG1, kPlate_2_B1_120MAIRVTX70Rat IgG2a, kPlate_2_B10_129CD1974B12Rat IgG2a, kPlate_2_B11_130CD47miap301Rat IgG2a, kPlate_2_B12_131CD98RL388Rat IgG2a, kPlate_2_B2_121CD146ME-9F1Rat IgG2a, kPlate_2_B3_122VISTAMIH63Rat IgG2a, kPlate_2_B4_123CD8a53-6.7Rat IgG2a, kPlate_2_B5_124CD275HK5.3Rat IgG2a, kPlate_2_B6_125CD34MEC14.7MEC14.7Rat IgG2a, kPlate_2_B7_126Sca_1D7Rat IgG2a, kPlate_2_B8_127CD403 / 23Rat IgG2a, kPlate_2_B9_128B220RA3-6B2Rat IgG2a, kPlate_2_C1_132CD14Sa14-2Rat IgG2a, kPlate_2_C10_141Tim4RMT4-54Rat IgG2a, kPlate_2_C11_142CD71RI7217Rat IgG2a, kPlate_2_C12_143H2M1 / 42Rat IgG2a, kPlate_2_C2_133CD107a1D4BRat IgG2a, kPlate_2_C3_134CD18M18 / 2Rat IgG2a, kPlate_2_C4_135Ly6G1A8Rat IgG2a, kPlate_2_C5_136CD21, CD357E9Rat IgG2a, kPlate_2_C6_137Mac2M3 / 38Rat IgG2a, kPlate_2_C7_138CD1999B1Rat IgG2a, kPlate_2_C8_139Ly516C3Rat IgG2a, kPlate_2_C9_140IgD11-26c.2aRat IgG2a, kPlate_2_D1_144CD45RBC363-16ARat IgG2a, kPlate_2_D10_153CD105MJ7 / 18Rat IgG2a, kPlate_2_D12_1544_1BB LigandTKS-1Rat IgG2a, kPlate_2_D2_145CD326G8.8Rat IgG2a, kPlate_2_D3_146IgMRMM-1Rat IgG2a, kPlate_2_D4_147CD155TX56Rat IgG2a, kPlate_2_D5_148CD200ROX-110Rat IgG2a, kPlate_2_D6_149CD254IK22 / 5Rat IgG2a, kPlate_2_D7_150IL21R4A9Rat IgG2a, kPlate_2_D8_151CD276RTAA15Rat IgG2a, kPlate_2_D9_152CD9MZ3Rat IgG2a, kPlate_2_E1_155CD265R12-31Rat IgG2a, kPlate_2_E10_164F4 / 80BM8Rat IgG2a, kPlate_2_E11_165CD9418d3Rat IgG2a, kPlate_2_E12_166CD2678F10Rat IgG2a, kPlate_2_E2_156TLR4MTS510Rat IgG2a, kPlate_2_E3_157CD196D5Rat IgG2a, kPlate_2_E4_158LPAM_1DATK32Rat IgG2a, kPlate_2_E5_159CD62LMEL-14Rat IgG2a, kPlate_2_E6_160CD23B3B4Rat IgG2a, kPlate_2_E7_161CD553-7.3Rat IgG2a, kPlate_2_E8_162CD273TY25Rat IgG2a, kPlate_2_E9_163CD31390Rat IgG2a, kPlate_2_F1_167Ly_49AYE1 / 48.10.6Rat IgG2a, kPlate_2_F10_176PDC_TREM4A6Rat IgG2a, kPlate_2_F11_177CD135A2F10Rat IgG2a, kPlate_2_F12_178CD127A7R34Rat IgG2a, kPlate_2_F3_169CD11aM17 / 4Rat IgG2a, kPlate_2_F4_170LT beta R5G11Rat IgG2a, kPlate_2_F6_172CD106429 (MVCAM.A)Rat IgG2a, kPlate_2_F7_173CD365RMT1-4Rat IgG2a, kPlate_2_F8_174CD115AFS98Rat IgG2a, kPlate_2_F9_175CD140aAPA5Rat IgG2a, kPlate_2_G1_179CD140bAPB5Rat IgG2a, kPlate_2_G10_188CD200R3Ba13Rat IgG2a, kPlate_2_G11_189MAIR_IVTX69Rat IgG2a, kPlate_2_G12_190Ly49D4E5Rat IgG2a, kPlate_2_G2_180ESAM1G8 / ESAMRat IgG2a, kPlate_2_G3_181CD200OX-90Rat IgG2a, kPlate_2_G4_182CD309Avas12Rat IgG2a, kPlate_2_G5_183TLT_2MIH47Rat IgG2a, kPlate_2_G6_184CD253N2B2Rat IgG2a, kPlate_2_G7_185CD33529A1.4Rat IgG2a, kPlate_2_G8_186CD205NLDC-145Rat IgG2a, kPlate_2_G9_187Galectin9108A2Rat IgG2a, kPlate_2_H1_191CD1235B11Rat IgG2a, kPlate_2_H10_200CD63NVG-2Rat IgG2a, kPlate_2_H11_201CD49e5H10-27(MFR5)Rat IgG2a, kPlate_2_H12_202CD193J073E5Rat IgG2a, kPlate_2_H2_192CD35511-5 / CRTAMRat IgG2a, kPlate_2_H3_193CD1693D6.112Rat IgG2a, kPlate_2_H4_194CD138281-2Rat IgG2a, kPlate_2_H5_195CD1607H1Rat IgG2a, kPlate_2_H6_196CD39Duha59Rat IgG2a, kPlate_2_H7_197GARPF011-5Rat IgG2a, kPlate_2_H8_198CD179aR3Rat IgG2a, kPlate_2_H9_199CD3715D3 / CLEC12ARat IgG2a, kPlate_3_A10_212MAdCAM1MECA-367Rat IgG2a, kPlate_3_A11_213MERTK2B10C42Rat IgG2a, kPlate_3_A12_214CD226TX42.1Rat IgG2a, kPlate_3_A2_204CD300LGZAQ5Rat IgG2a, kPlate_3_A3_205CD301LOM-8.7Rat IgG2a, kPlate_3_A4_206IL33RaDIH9Rat IgG2a, kPlate_3_A5_207CD3043E12Rat IgG2a, kPlate_3_A6_208CD6OX-129Rat IgG2a, kPlate_3_A7_209CD100BMA-12Rat IgG2a, kPlate_3_A8_210CD104346-11ARat IgG2a, kPlate_3_A9_211CD182SA044G4Rat IgG2a, kPlate_3_B1_215Ly6KMK34Rat IgG2a, kPlate_3_B10_224CD43S11Rat IgG2b, kPlate_3_B11_225FR412A5Rat IgG2b, kPlate_3_B12_226CD1d1B1Rat IgG2b, kPlate_3_B2_216CD16 / 3293Rat IgG2a, λPlate_3_B3_217CD150TC15-12F12.2Rat IgG2a, λPlate_3_B4_218CD25PC61Rat IgG2a, λPlate_3_B5_219CD3890Rat IgG2a, λPlate_3_B6_220CD133315-2C11Rat IgG2a, λPlate_3_B7_221CD301bURA-1Rat IgG2a, λPlate_3_B8_222CD34_SA376A4SA376A4Rat IgG2a, λPlate_3_B9_223Isotype_rIgG2bRTK4530Rat IgG2b, kPlate_3_C1_227CD70FR70Rat IgG2b, kPlate_3_C10_236CD24M1 / 69Rat IgG2b, kPlate_3_C11_237Gr1RB6-8C5Rat IgG2b, kPlate_3_C12_238CD86PO3Rat IgG2b, kPlate_3_C2_228CD4GK1.5Rat IgG2b, kPlate_3_C3_229IA / IEM5 / 114.15.2Rat IgG2b, kPlate_3_C4_230CD153RM153Rat IgG2b, kPlate_3_C5_231CD54YN1 / 1.7.4Rat IgG2b, kPlate_3_C6_23233D133D1Rat IgG2b, kPlate_3_C7_233CD90.230-H12Rat IgG2b, kPlate_3_C8_234TER119TER-119Rat IgG2b, kPlate_3_C9_235CD49dR1-2Rat IgG2b, kPlate_3_D1_239CD11bM1 / 70Rat IgG2b, kPlate_3_D10_248CD317A2Rat IgG2b, kPlate_3_D11_249CD27410F.9G2Rat IgG2b, kPlate_3_D12_250CD1172B8Rat IgG2b, kPlate_3_D2_240CD4530-F11Rat IgG2b, kPlate_3_D3_241CD279RMP1-30Rat IgG2b, kPlate_3_D4_242RAE1yCX1Rat IgG2b, kPlate_3_D5_243CD8bYTS156.7.7Rat IgG2b, kPlate_3_D7_245CD126D7715A7Rat IgG2b, kPlate_3_D8_246CD317927Rat IgG2b, kPlate_3_D9_247CD132TUGm2Rat IgG2b, kPlate_3_E1_251CD8820 / 70Rat IgG2b, kPlate_3_E10_260CD1304H1B35Rat IgG2b, kPlate_3_E11_261CD198SA214G2Rat IgG2b, kPlate_3_E12_262CD20SA275A11Rat IgG2b, kPlate_3_E2_252CD93AA4.1Rat IgG2b, kPlate_3_E3_253CD252RM134LRat IgG2b, kPlate_3_E4_254MD1MD-113Rat IgG2b, kPlate_3_E5_255CD357YGITR 765Rat IgG2b, kPlate_3_E6_256CD185L138D7Rat IgG2b, kPlate_3_E7_257CD37Duno85Rat IgG2b, kPlate_3_E8_258CD300c / dTX52Rat IgG2b, kPlate_3_E9_259CD186 (CXCR6)SA051D1Rat IgG2b, kPlate_3_F1_263CD124I015F8Rat IgG2b, kPlate_3_F10_272GL7GL7Rat IgM, kPlate_3_F11_273Isotype_SHIgGSHG-1Syrian Hamster IgGPlate_3_F12_274CD2837.51Syrian Hamster IgGPlate_3_F2_264IL23R12B2B64Rat IgG2b, kPlate_3_F3_265CD184L276F12Rat IgG2b, kPlate_3_F4_266CD2RM2-5Rat IgG2b, λPlate_3_F5_267Isotype_rIgG2cRTK4174Rat IgG2c, kPlate_3_F6_268Ly6CHK1.4Rat IgG2c, kPlate_3_F7_269Ly6D49-H4Rat IgG2c, kPlate_3_F8_270Isotype_rIgMRTK2118Rat IgM, kPlate_3_F9_271CD49b_IgMDX5Rat IgM, kPlate_3_G1_275Podoplanin8.1.1Syrian Hamster IgGPlate_3_G2_276CD13717B5Syrian Hamster IgGPlate_3_G3_277CD27815F9Syrian Hamster IgGPlate_3_G4_278KLRG12F1 / KLRG1Syrian Hamster IgGPlate_3_G5_279Ly49CFIH14B11Syrian Hamster IgG

[0150] TABLE 2(related to FIG. 2). Cell type identification of PhenoGraph clustersPhenographLabelMarkers1Transitional Pre-MonocytesCD184hi, Ly6Chi, CD115,(tpMo)CX3CR1, CD62Lhi2Pro B cellsB220, CD19, CD16 / 32lo,CD48lo3cMoP, tpMoCD34, Ly6C, CD115, CD62L4IgM+ B CellsIgM, B2205Dendritic Cells / preDCsFLT3, CD11c, SiglecH,IFNAR1, CD3176EosinophilsSiglecF, F4 / 80, CD417NK, T cells, NKT cellsNK1.1, CD3, NKG2D8MegakaryocytesCD41, CD61, SSChi9Immature NeutrophilsCD371, CD63, Ly6G, CD8110Mature NeutrophilsCD182hi, Ly6G, Gr1, CD11b11Classical monocytesCD115, Ly6C, CD11b(Ly6Chi Monocytes)12Mature NeutrophilsCD182hi, Ly6G, Gr1, CD11b13Mature NeutrophilsCD182hi, Ly6G, Gr1, CD11b14Recirculating / AgedCD43lo, Ly6G, CD11bhi,NeutrophilsCD62Llo, CD182lo15Basophils, Mast cellsCD220R, CD49b, IL33R,CD16 / 32hi, cKit, CD12316Ly6Chi Monocytes downre-CD115, Ly6C, CD11bgulated in CD115 duringharvest17Mature NeutrophilsCD182hi, Ly6G, Gr1, CD11b18HSPCscKit, Sca-1, Flt3, CD48,CD11b−19Pre-pro B CellsB220lo, CD2−, CD14, CD19−,CD10320Stromal CellsCD140a, CD140b, CD45−, CD14421Transitional Pre-MonocytesCD184hi, Ly6Chi, CD115,(tpMo)CX3CR1, CD62Lhi22Red Blood CellsCD147, Ter11923pre-NeutrophilscKit, Gr1, CD11b, CD43, Ly6C24Ly6C− Monocytes (non-CD43, CD115, CX3CR1, CD11cclassical monocytes)25Recirculating Ly6ChiLy6C, CX3CR1, CD62L,Classical MonocytesCD16 / 32, CD11526pre B cellsCD16 / 32hi, B220, CD1927IgD+ B cellsIgD, B220

[0151] TABLE 3(Related to FIG. 7). List of surface markers testedin human cord blood LEGENDScreen ™.LocationMarkerCloneIsotypePlate_1_A1_001BlankPlate_1_A10_009CD2RPA-2.10mouse IgG1, kPlate_1_A12_011B7-H4MIH43mouse IgG1, kPlate_1_A3_003CCR106588-5Armenian Hamster IgGPlate_1_A4_004CD278C398.4AArmenian Hamster IgGPlate_1_A5_005IFN-γ R b chain2HUB-159Hamster IgGPlate_1_A7_006CD46TRA-2-10Mouse IgG1Plate_1_A8_007CD70113-16Mouse IgG1Plate_1_A9_008CD1aHI149mouse IgG1, kPlate_1_B1_012Cadherin 1116G5mouse IgG1, kPlate_1_B10_021CD111R1.302mouse IgG1, kPlate_1_B11_022CD112TX31mouse IgG1, kPlate_1_B12_023CD114LMM741mouse IgG1, kPlate_1_B2_013CD10HI10amouse IgG1, kPlate_1_B3_014CD100A8mouse IgG1, kPlate_1_B4_015CD103Ber-ACT8mouse IgG1, kPlate_1_B5_016CD105 (Endoglin)SN6hmouse IgG1, kPlate_1_B6_017CD106STAmouse IgG1, kPlate_1_B7_018CD107aH4A3mouse IgG1, kPlate_1_B8_019CD107bH4B4mouse IgG1, kPlate_1_B9_020CD109W7C5mouse IgG1, kPlate_1_C1_024CD1164H1mouse IgG1, kPlate_1_C10_033CD13WM15mouse IgG1, kPlate_1_C11_034CD1311C1mouse IgG1, kPlate_1_C12_035CD134Ber-ACT35mouse IgG1, k(ACT35)Plate_1_C2_025CD117104D2mouse IgG1, kPlate_1_C3_026CD119GIR-208mouse IgG1, kPlate_1_C4_027CD11aHI111mouse IgG1, kPlate_1_C5_028CD11bICRF44mouse IgG1, kPlate_1_C6_029CD122TU27mouse IgG1, kPlate_1_C7_030CD1236H6mouse IgG1, kPlate_1_C8_031CD126UV4mouse IgG1, kPlate_1_C9_032CD127A019D5mouse IgG1, kPlate_1_D1_036CD135BV10A4H2mouse IgG1, kPlate_1_D10_045CD1435-369mouse IgG1, kPlate_1_D11_046CD146P1H12mouse IgG1, kPlate_1_D12_047CD148A3mouse IgG1, kPlate_1_D2_037CD1374B4-1mouse IgG1, kPlate_1_D3_0384-1BB Ligand5F4mouse IgG1, kPlate_1_D4_039CD138MI15mouse IgG1, kPlate_1_D5_041CD1463D3mouse IgG1, kPlate_1_D6_040CD140a16A1mouse IgG1, kPlate_1_D7_042CD140b18A2mouse IgG1, kPlate_1_D8_043CD141M80mouse IgG1, kPlate_1_D9_044CD142NY2mouse IgG1, kPlate_1_E1_048CD15W6D3mouse IgG1, kPlate_1_E10_057CD163GHI / 61mouse IgG1, kPlate_1_E11_058CD16467D2mouse IgG1, kPlate_1_E12_059CD165SN2 (N6-D11)mouse IgG1, kPlate_1_E2_049CD150A12 (7D4)mouse IgG1, kPlate_1_E3_050CD15150-6mouse IgG1, kPlate_1_E4_051CD15424-31mouse IgG1, kPlate_1_E5_052CD156cSHM14mouse IgG1, kPlate_1_E6_053CD158e1DX9mouse IgG1, kPlate_1_E7_054CD163G8mouse IgG1, kPlate_1_E8_055CD161HP-3G10mouse IgG1, kPlate_1_E9_056CD162KPL-1mouse IgG1, kPlate_1_F1_060CD1663A6mouse IgG1, kPlate_1_F10_069CD180MHR73-11mouse IgG1, kPlate_1_F11_070CD1825E8 / CXCR2mouse IgG1, kPlate_1_F12_071CD183G025H7mouse IgG1, kPlate_1_F2_061CD1697-239mouse IgG1, kPlate_1_F3_062CD1701A5mouse IgG1, kPlate_1_F4_063CD172a / b (SIRPα / β)SE5A5mouse IgG1, kPlate_1_F5_064CD172g (SIRPγ)LSB2.20mouse IgG1, kPlate_1_F6_065CD178NOK-1mouse IgG1, kPlate_1_F7_066CD179aHSL96mouse IgG1, kPlate_1_F8_067CD179bHSL11mouse IgG1, kPlate_1_F9_068CD18TS1 / 18mouse IgG1, kPlate_1_G1_072CD185J252D4mouse IgG1, kPlate_1_G10_081CD203cNP4D6mouse IgG1, kPlate_1_G11_082CD205HD83mouse IgG1, kPlate_1_G12_083CD20615-2mouse IgG1, kPlate_1_G2_073CD19HIB19mouse IgG1, kPlate_1_G3_074CD1915F10B29mouse IgG1, kPlate_1_G4_075CD194L291H4mouse IgG1, kPlate_1_G5_076CD1bSN13 (K5-1B8)mouse IgG1, kPlate_1_G6_077CD1cL161mouse IgG1, kPlate_1_G7_078CD200OX-104mouse IgG1, kPlate_1_G8_079CD200ROX-108mouse IgG1, kPlate_1_G9_080CD202b33.1 (Ab33)mouse IgG1, kPlate_1_H10_093CD229HLy-9.1.25mouse IgG1, kPlate_1_H11_094CD23EBVCS-5mouse IgG1, kPlate_1_H2_085CD21Bu32mouse IgG1, kPlate_1_H3_086CD213α1SS12Bmouse IgG1, kPlate_1_H4_087CD213α2SHM38mouse IgG1, kPlate_1_H5_088CD218aH44mouse IgG1, kPlate_1_H6_089CD2211H7 / CD221mouse IgG1, kPlate_1_H7_090CD223 (LAG-3)11C3C65mouse IgG1, kPlate_1_H8_091CD22611A8mouse IgG1, kPlate_1_H9_092CD22716Amouse IgG1, kPlate_2_A10_009CD26811C1mouse IgG1, kPlate_2_A11_010CD27M-T271mouse IgG1, kPlate_2_A2_001CD244 (2B4)C1.7mouse IgG1, kPlate_2_A3_002CD245DY12mouse IgG1, kPlate_2_A4_003CD25M-A251mouse IgG1, kPlate_2_A5_004CD25211C3.1mouse IgG1, kPlate_2_A6_005CD261DJR1mouse IgG1, kPlate_2_A7_006CD262DJR2-4 (7-8)mouse IgG1, kPlate_2_A8_007CD263DJR3mouse IgG1, kPlate_2_A9_008CD266ITEM-1mouse IgG1, kPlate_2_B1_012CD2759F.8A4mouse IgG1, kPlate_2_B10_021CD30BY88mouse IgG1, kPlate_2_B11_022CD300cTX45mouse IgG1, kPlate_2_B12_023CD3097D4-6mouse IgG1, kPlate_2_B2_013CD276MIH42mouse IgG1, kPlate_2_B3_014CD277BT3.1mouse IgG1, kPlate_2_B4_015CD279EH12.2H7mouse IgG1, kPlate_2_B5_016CD28CD28.2mouse IgG1, kPlate_2_B6_017CD29TS2 / 16mouse IgG1, kPlate_2_B7_018CD2903C10C5mouse IgG1, kPlate_2_B8_019CD298LNH-94mouse IgG1, kPlate_2_B9_020CD3UCHT1mouse IgG1, kPlate_2_C1_024CD31WM59mouse IgG1, kPlate_2_C10_033CD336P44-8mouse IgG1, kPlate_2_C11_034CD337P30-15mouse IgG1, kPlate_2_C12_035CD34581mouse IgG1, kPlate_2_C2_025CD3141D11mouse IgG1, kPlate_2_C3_026CD317RS38Emouse IgG1, kPlate_2_C4_027CD32467A4mouse IgG1, kPlate_2_C5_028CD3258C11mouse IgG1, kPlate_2_C6_029CD3286-434mouse IgG1, kPlate_2_C7_030CD33WM53mouse IgG1, kPlate_2_C8_031CD3344FR6D3mouse IgG1, kPlate_2_C9_032CD3359E2mouse IgG1, kPlate_2_D1_036CD34024D2mouse IgG1, kPlate_2_D10_045CD38HIT2mouse IgG1, kPlate_2_D11_046CD39A1mouse IgG1, kPlate_2_D12_047CD4RPA-T4mouse IgG1, kPlate_2_D2_037CD344CH3A4A7mouse IgG1, kPlate_2_D3_038CD35E11mouse IgG1, kPlate_2_D4_039CD354TREM-26mouse IgG1, kPlate_2_D5_040CD36017A12mouse IgG1, kPlate_2_D6_041CD3651D12mouse IgG1, kPlate_2_D7_042CD366F38-2E2mouse IgG1, kPlate_2_D8_043CLEC4A9E8mouse IgG1, kPlate_2_D9_044CD36L1m1b9mouse IgG1, kPlate_2_E1_048CD405C3mouse IgG1, kPlate_2_E10_057CD49bP1E6-C5mouse IgG1, kPlate_2_E11_058CD49cASC-1mouse IgG1, kPlate_2_E12_059CD49d9F10mouse IgG1, kPlate_2_E2_049CD41HIP8mouse IgG1, kPlate_2_E3_050CD42bHIP1mouse IgG1, kPlate_2_E4_051CD43CD43-10G7mouse IgG1, kPlate_2_E5_052CD44BJ18mouse IgG1, kPlate_2_E6_053CD45HI30mouse IgG1, kPlate_2_E7_054CD47CC2C6mouse IgG1, kPlate_2_E8_055CD48BJ40mouse IgG1, kPlate_2_E9_056CD49aTS2 / 7mouse IgG1, kPlate_2_F1_060CD5UCHT2mouse IgG1, kPlate_2_F10_069CD62LDREG-56mouse IgG1, kPlate_2_F11_070CD62PAK4mouse IgG1, kPlate_2_F2_061CD50CBR-IC3 / 1mouse IgG1, kPlate_2_F3_062CD54HA58mouse IgG1, kPlate_2_F4_063CD55JS11mouse IgG1, kPlate_2_F5_064CD56 (NCAM)5.1H11mouse IgG1, kPlate_2_F6_065CD58TS2 / 9mouse IgG1, kPlate_2_F7_066CD6BL-CD6mouse IgG1, kPlate_2_F8_067CD61VI-PL2mouse IgG1, kPlate_2_G10_081CD83HB15emouse IgG1, kPlate_2_G11_082CD8517G10.2mouse IgG1, kPlate_2_G12_083CD85kZM4.1mouse IgG1, kPlate_2_G2_073CD69FN50mouse IgG1, kPlate_2_G4_075CD74LN2mouse IgG1, kPlate_2_G5_076CD79bCB3-1mouse IgG1, kPlate_2_G6_077CD8aSK1mouse IgG1, kPlate_2_G7_078CD802D10mouse IgG1, kPlate_2_G8_079CD815A6mouse IgG1, kPlate_2_G9_080CD82ASL-24mouse IgG1, kPlate_2_H1_084CD87VIM5mouse IgG1, kPlate_2_H10_093CD97VIM3bmouse IgG1, kPlate_2_H11_094CD993B2 / TA8mouse IgG1, kPlate_2_H12_095CXCL1622-19-12mouse IgG1, kPlate_2_H2_085CD89A59mouse IgG1, kPlate_2_H3_086CD8aRPA-T8mouse IgG1, kPlate_2_H4_087CD9HI9amouse IgG1, kPlate_2_H5_088CD905E10mouse IgG1, kPlate_2_H6_089CD93VIMD2mouse IgG1, kPlate_2_H7_090CD94DX22mouse IgG1, kPlate_2_H8_091CD95DX2mouse IgG1, kPlate_2_H9_092CD96NK92.39mouse IgG1, kPlate_3_A10_009HVEM122mouse IgG1, kPlate_3_A11_010Ig light chain κMHK-49mouse IgG1, kPlate_3_A12_011IgMMHM-88mouse IgG1, kPlate_3_A2_001DLL1MHD1-314mouse IgG1, kPlate_3_A3_002DLL4MHD4-46mouse IgG1, kPlate_3_A4_003DR3JD3mouse IgG1, kPlate_3_A5_004EGFRAY13mouse IgG1, kPlate_3_A6_005CD357108-17mouse IgG1, kPlate_3_A7_006GPR19K152D10mouse IgG1, kPlate_3_A8_007GPR56CG4mouse IgG1, kPlate_3_A9_008HLA-E3D12mouse IgG1, kPlate_3_B1_012CD3602G1-K12mouse IgG1, kPlate_3_B10_020TNAPW8B2mouse IgG1, kPlate_3_B11_021MUC-13TCC16mouse IgG1, kPlate_3_B12_022NKp805D12mouse IgG1, kPlate_3_B2_013Integrin α9β1Y9A2mouse IgG1, kPlate_3_B3_014Jagged 2MHJ2-523mouse IgG1, kPlate_3_B4_015Ksp37TDA3mouse IgG1, kPlate_3_B5_016LAPTW4-2F8mouse IgG1, kPlate_3_B6_017LY6G6D13.8mouse IgG1, kPlate_3_B7_018MERTK590H11G1E3mouse IgG1, kPlate_3_B8_019MSCW7C6mouse IgG1, kPlate_3_C1_023Notch 1MHN1-519mouse IgG1, kPlate_3_C10_032Siglec-87C9mouse IgG1, kPlate_3_C11_033Siglec-9K8mouse IgG1, kPlate_3_C12_034SSEA-58E11mouse IgG1, kPlate_3_C2_024Notch3MHN3-21mouse IgG1, kPlate_3_C3_025Notch 4MHN4-2mouse IgG1, kPlate_3_C4_026NPC57D2mouse IgG1, kPlate_3_C5_027CD352NT-7mouse IgG1, kPlate_3_C6_028PSMALNI-17mouse IgG1, kPlate_3_C8_030Siglec-105G6mouse IgG1, kPlate_3_C9_031CD328S7.7mouse IgG1, kPlate_3_D1_035SUSD2W5C5mouse IgG1, kPlate_3_D10_044VEGFR-39D9F9mouse IgG1, kPlate_3_D12_045APCDD17.13mouse IgG2a, kPlate_3_D2_036TCR α / βIP26mouse IgG1, kPlate_3_D4_038Tim-49F4mouse IgG1, kPlate_3_D5_039TLT-2MIH61mouse IgG1, kPlate_3_D6_040TM4SF20C9mouse IgG1, kPlate_3_D7_041TRA-2-49TRA-2-49 / 6Emouse IgG1, kPlate_3_D8_042TRA-2-54TRA-2-54 / 2Jmouse IgG1, kPlate_3_D9_043TSLPR1B4mouse IgG1, kPlate_3_E1_046CD272MIH26mouse IgG2a, kPlate_3_E10_055CD155TX24mouse IgG2a, kPlate_3_E11_056CD158bDX27mouse IgG2a, kPlate_3_E12_057CD18412G5mouse IgG2a, kPlate_3_E2_047CD198L263G8mouse IgG2a, kPlate_3_E3_048CCRL2K097F7mouse IgG2a, kPlate_3_E4_049CD102CBR-IC2 / 2mouse IgG2a, kPlate_3_E5_050CD10458XB4mouse IgG2a, kPlate_3_E6_051CD124G077F6mouse IgG2a, kPlate_3_E7_052CD1302E1B02mouse IgG2a, kPlate_3_E8_053CD144BV9mouse IgG2a, kPlate_3_E9_054CD152 (CTLA-4)BNI3mouse IgG2a, kPlate_3_F1_058CD186K041E5mouse IgG2a, kPlate_3_F10_067CD26BA5bmouse IgG2a, kPlate_3_F11_068CD26919F2mouse IgG2a, kPlate_3_F12_069CD282TL2.1mouse IgG2a, kPlate_3_F2_059CD192K036C2mouse IgG2a, kPlate_3_F3_060CD197G043H7mouse IgG2a, kPlate_3_F4_061CD199L053E8mouse IgG2a, kPlate_3_F5_062CD2099E9A8mouse IgG2a, kPlate_3_F6_063CD217W15177Amouse IgG2a, kPlate_3_F7_064CD230 (Prion)3F4mouse IgG2a, kPlate_3_F8_065CD24ML5mouse IgG2a, kPlate_3_F9_066CD243UIC2mouse IgG2a, kPlate_3_G1_070CD284HTA125mouse IgG2a, kPlate_3_G10_078CD3708F9mouse IgG2a, kPlate_3_G11_079CD37150C1mouse IgG2a, kPlate_3_G12_080CD45ROUCHL1mouse IgG2a, kPlate_3_G2_071CD301H037G3mouse IgG2a, kPlate_3_G3_072CD303201Amouse IgG2a, kPlate_3_G4_073CD30412C2mouse IgG2a, kPlate_3_G5_074CD307e509f6mouse IgG2a, kPlate_3_G6_093CD323SHM33mouse IgG2a, kPlate_3_G7_075CD357108-17mouse IgG2a, kPlate_3_G8_076CD365-271mouse IgG2a, kPlate_3_G9_077CD36915E2mouse IgG2a, kPlate_3_H1_081CD51NKI-M9mouse IgG2a, kPlate_3_H10_090Ganglioside GD214G2amouse IgG2a, kPlate_3_H11_091GPR83K07JP05mouse IgG2a, kPlate_3_H12_092HLA-A, B, CW6 / 32mouse IgG2a, kPlate_3_H2_082CD59p282 (H19)mouse IgG2a, kPlate_3_H3_083CD7CD7-6B7mouse IgG2a, kPlate_3_H4_084CD71CY1G4mouse IgG2a, kPlate_3_H5_085CD84CD84.1.21mouse IgG2a, kPlate_3_H6_086CD88S5 / 1mouse IgG2a, kPlate_3_H7_087CD355Cr24.1mouse IgG2a, kPlate_3_H8_088erbB31B4C3mouse IgG2a, kPlate_3_H9_089FPR3K102B9mouse IgG2a, kPlate_4_A10_010SUSD2W3D5mouse IgG2a, kPlate_4_A11_011Notch 2MHN2-25mouse IgG2a, kPlate_4_A12_012TACSTD2NY18mouse IgG2a, kPlate_4_A2_002HLA-DRL243mouse IgG2a, kPlate_4_A3_003Ig light chain λMHL-38mouse IgG2a, kPlate_4_A4_004IgDIA6-2mouse IgG2a, kPlate_4_A5_005IL-28RAMHLICR2amouse IgG2a, kPlate_4_A6_006integrin β5AST-3Tmouse IgG2a, kPlate_4_A7_007KLRG1SA231A2mouse IgG2a, kPlate_4_A8_008LOX-115C4mouse IgG2a, kPlate_4_A9_009MICA / MICB6D4mouse IgG2a, kPlate_4_B1_013TIGIT (VSTM3)A15153Gmouse IgG2a, kPlate_4_B10_021CD196G034E3mouse IgG2b, kPlate_4_B11_022CD1d51.1mouse IgG2b, kPlate_4_B12_023CD202H7mouse IgG2b, kPlate_4_B3_014C3aRhC3aRZ8mouse IgG2b, kPlate_4_B4_015CCX-CKR (CCRL1)13E11mouse IgG2b, kPlate_4_B5_016CD11cS-HCL-3mouse IgG2b, kPlate_4_B6_017CD129AH9R7mouse IgG2b, kPlate_4_B7_018CD158HP-MA4mouse IgG2b, kPlate_4_B8_019CD1818F1 / CXCR1mouse IgG2b, kPlate_4_B9_020CD1935E8mouse IgG2b, kPlate_4_C1_024CD22S-HCL-1mouse IgG2b, kPlate_4_C10_033CD3689B9mouse IgG2b, kPlate_4_C11_034CD45RAHI100mouse IgG2b, kPlate_4_C12_035CD45RBMEM-55mouse IgG2b, kPlate_4_C2_025CD220B6.220mouse IgG2b, kPlate_4_C3_026CD235abHIR2mouse IgG2b, kPlate_4_C4_027CD258T5-39mouse IgG2b, kPlate_4_C5_028CD27429E.2A3mouse IgG2b, kPlate_4_C6_029CD319162.1mouse IgG2b, kPlate_4_C7_030CD32FUN-2mouse IgG2b, kPlate_4_C8_031CD3269C4mouse IgG2b, kPlate_4_C9_032CD3385D3mouse IgG2b, kPlate_4_D1_036CD49eNKI-SAM-1mouse IgG2b, kPlate_4_D10_045Dopamine ReceptorL205G1mouse IgG2b, kD1 (DRD1)Plate_4_D11_046EphA2SHM16mouse IgG2b, kPlate_4_D12_047FcεRIαAER-37 (CRA-1)mouse IgG2b, kPlate_4_D2_037CD52HI186mouse IgG2b, kPlate_4_D3_038CD66a / c / eASL-32mouse IgG2b, kPlate_4_D4_039CD85h24mouse IgG2b, kPlate_4_D5_040CD85GHI / 75mouse IgG2b, kPlate_4_D6_041CD86IT2.2mouse IgG2b, kPlate_4_D7_042CD92VIM15bmouse IgG2b, kPlate_4_D8_043CXCR78F11-M16mouse IgG2b, kPlate_4_D9_044Delta Opioid ReceptorDOR7D2A4mouse IgG2b, kPlate_4_E1_048GARP7B11mouse IgG2b, kPlate_4_E10_056SSEA-4MC-813-70Mouse IgG3, kPlate_4_E12_057Sialyl Lewis X (dimeric)FH6Mouse IgM, kPlate_4_E2_049CD215JM7A4mouse IgG2b, kPlate_4_E3_050Lymphotoxin β Receptor31G4D8mouse IgG2b, kPlate_4_E4_051MRGX2K125H4mouse IgG2b, kPlate_4_E5_052TMEM8ASA065C3mouse IgG2b, kPlate_4_E6_053CD254MIH24mouse IgG2b, kPlate_4_E7_054CD318CUB1mouse IgG2b, kPlate_4_E9_055CD255CARL-1Mouse IgG3, kPlate_4_F1_058TRA-1-81TRA-1-81Mouse IgM, kPlate_4_F10_066CD120b3G7A02Rat IgG2a, kPlate_4_F11_067CD2103F9Rat IgG2a, kPlate_4_F12_068CD2671A1Rat IgG2a, kPlate_4_F2_059CD160BY55Mouse IgM, kPlate_4_F3_060CD57HNK-1Mouse IgM, kPlate_4_F4_061CD66bG10F5Mouse IgM, kPlate_4_F5_062TRA-1-60-RTRA-1-60-RMouse IgM, kPlate_4_F7_063CD1159-4D2-1E4Rat IgG1, kPlate_4_F8_064CD201RCR-401Rat IgG1, kPlate_4_G1_069CD294BM16Rat IgG2a, kPlate_4_G10_077CD132TUGh4Rat IgG2b, kPlate_4_G11_078CD195J418F1Rat IgG2b, kPlate_4_G12_079CX3CR12A9-1Rat IgG2b, kPlate_4_G2_070CD49fGoH3Rat IgG2a, kPlate_4_G3_071CD85MKT5.1Rat IgG2a, kPlate_4_G4_072CD85d42D1Rat IgG2a, kPlate_4_G5_073IgG FcM1310G05Rat IgG2a, kPlate_4_G6_074Integrin β7FIB504Rat IgG2a, kPlate_4_G7_075XCR1S15046ERat IgG2a, kPlate_4_G8_076PodoplaninNC-08Rat IgG2a, lPlate_4_H2_080SSEA-3MC-631Rat IgM, k

[0152] TABLE 4Key resources tableREAGENTSOURCEIDENTIFIERAntibodiesB220 (Clone RA3-6B2)Thermo FisherCat# 25-0452; RRID: AB_2341160CD81 (Clone Eat-2)BiolegendCat# 104906, RRID: AB_2076266CD106 (Clone 429BiolegendCat# 105716, RRID: AB_1595489(MVCAM.A))cKit (Clone 2B8)Thermo FisherCat# 62-1171-82, RRID: AB_2637141CD11b (Clone M1 / 70)Thermo FisherCat# 63-0112-80, RRID: AB_2637407CD115 (Clone AFS98)BiolegendCat# 135510, RRID: AB_2085221Flt3 (Clone A2F10)BiolegendCat# 135308, RRID: AB_1953267NK1.1 (Clone PK136)Thermo FisherCat# 13-5941-81, RRID: AB_466803B220 (Clone RA3-6B2)Thermo FisherCat# 13-0452-82, RRID: AB_466449CD90.2 (Clone 53-2.1)BiolegendCat# 140314, RRID: AB_10643274F4 / 80 (Clone BM8)BiolegendCat# 123118, RRID: AB_893477CD16 / 32 (Clone 2.4G2)BD HorizonCat# 565502, RRID: AB_2739269CD34 (Clone RAM34)Thermo FisherCat# 13-0341-81, RRID: AB_466424Gr1 (Clone RB6-8C5)Thermo FisherCat# 45-5931-80; RRID: AB_906247Ly6C (Clone HK1.4)BiolegendCat# 128026; RRID: AB_10640120Ly6G (Clone 1A8)BiolegendCat# 127618; RRID: AB_1877261Sca-1 (Clone D7)BiolegendCat# 108114; RRID: AB_493596Siglec-F (Clone E50-BD BiosciencesCat# 562757; RRID: AB_3943412440)CXCR2 (CloneBiolegendCat# 149306; RRID: AB_2565694SA044G4)CXCR4 (Clone 2B11)Thermo FisherCat# 13-9991-82; RRID: AB_10609202CD45.1 (Clone A20)BiolegendCat#110707; RRID: AB_313496CD45.2 (Clone 104)BiolegendCat#109807; RRID: AB_313444CD3 (Clone UCHT1)BiolegendCat#300440; RRID: AB_2562046CD10 (Clone HI10a)BiolegendCat#312208; RRID: AB_314919CD19 (Clone HIB19)BiolegendCat#302205; RRID: AB_314235CD56 (Clone HCD56)BiolegendCat#318304; RRID: AB_604100CD14 (Clone M5E2)BiolegendCat#301838; RRID: AB_2562909CD15 (Clone HI98)BD BiosciencesCat#564232; RRID: AB_2738686CD49d (Clone 9F10)BD BiosciencesCat#563645; RRID: AB_2738344CD66b (Clone G105F)BD BiosciencesCat#305111; RRID: AB_2563293CD101 (Clone BB27)BiolegendCat#331007; RRID: AB_2121761CD16 (Clone 3G8)BD BiosciencesCat#560248; RRID: AB_1645467CD34 (Clone 581)BiolegendCat#343515; RRID: AB_1877252CD117 (Clone 104D2)Thermo FisherCat#64-1178-42; RRID: AB_2734860CD45 (Clone 2D1)BiolegendCat368515; RRID: AB_2566375CD11b (ICRF44)BD BiosciencesCat#563839; RRID: AB_2716869CD38 (S17015F)BiolegendCat#303531; RRID: AB_2561527CD71 (CY1G4)BiolegendCat#334106; RRID: AB_2201481Chemicals, Peptides, andRecombinant Proteins1X RBC Lysis BuffereBioscienceCat# 00-4333-575-FluorouracilSigma-AldrichCat# F6627CountBright AbsoluteLifeCat# C36950Counting BeadsTechnologiesDAPILifeCat# D1306TechnologiesHema 3 ManualThermo FisherCat# 22-122911Staining SystemEQ Four ElementFluidigmCat# 201078Calibration BeadsHuman G-CSFAmgenCat# 100696800(Neupogen)MethoCult ™ M3234Stem CellCat# 03234TechnologiesStemSpan ™ SFEM IIStem CellCat# 09655TechnologiesCriticalCommercial AssaysERCC RNA Spike-InThermo FisherCat# 4456740MixMILLIPLEX MAPMerckCat# MCYTMAG-70K-PX32MouseCytokine / ChemokineMagnetic Bead Panel -Premixed 32 Plex -Immunology MultiplexAssayLEGENDScreen ™BiolegendCat# 700007Human KitLEGENDScreen ™BiolegendCat# 70000Mouse KitArcturus PicoPureThermo FisherCat# KIT0214RNA isolation kitDeposited DataBulk RNA-seq ofThis disclosureGEO:myeloid progenitorpopulationsSmart-Seq2 Single-This disclosureGEO:cell Dataset ofmyeloid precursorsTabula Muris BM 10×(Schaum etGEO: GSE109774single-cell RNA-seqal., 2018)datasetSingle-cell RNA-seq(Olsson etGEO: GSE70240of BM GMPsal., 2016)Experimental Models:Organisms / StrainsMouse: C57BL / 6JThe JacksonStock No: 000664LaboratoryMouse: Rosa26mT / mG:STOCKThe JacksonStock No: 007676Gt(ROSA)26Sortm4(ACTB-tdTomato, −EGFP)Luo / JLaboratoryMouse: Fucci-S / G2 / MRIKEN BRC,Stock No: RBRC02704(#474)Ibaraki, JapanMouse: C57BL / 6-Tg(UBC-The JacksonStock No: 04353GFP)30Scha / J; UBI-GFPLaboratoryMouse: B6.SJL-PtprcaThe JacksonStock No: 002014Pepcb / BoyJ; B6 Cd45.1LaboratoryMouse: Cebpe− / −H. P. Koeffler(Kyme et al., 2012)Software andAlgorithmsGraphPad Prism 7GraphPad Softwarehttp: / / www.graphpad.comFlowJo 10TreeStarhttp: / / flowjo.com / t-SNE(Van Der Maatenhttps: / / cran.r-project.org / web / packages / Rtsne / index.htmland Hinton, 2008)edgeR(Robinson ethttps: / / bioconductor.org / packages / release / bioc / html / edgeR.htmlal., 2009)pheatmapR packagehttps: / / cran.r-project.org / web / packages / pheatmap / index.htmlEnrichr(Chen et al.,http: / / amp.pharm.mssm.edu / Enrichr / 2013)Monocle 2(Qiu et al.,http: / / cole-trapnell-lab.github.io / monocle-release / docs / 2017)Seurat v3(Stuart ethttps: / / github.com / satijalab / seuratal., 2018)UMAP(McInnes ethttps: / / umap-learn.readthedocs.io / en / latest / al., 2018)SVM regression usedThe R foundationhttps: / / cran.r-project.org / web / packages / e1071 / in InfinityFlowR 3.6The R foundationhttps: / / www.r-project.org / REFERENCESAkashi, K., Traver, D., Miyamoto, T., and Weissman, I. L. (2000). A clonogenic common myeloid progenitor that gives rise to all myeloid lineages. Nature 404, 193-197.

[0154] Arinobu, Y., Iwasaki, H., Gurish, M. F., Mizuno, S. I., Shigematsu, H., Ozawa, H., Tenen, D. G., Austen, K. F., and Akashi, K. (2005). Developmental checkpoints of the basophil / mast cell lineages in adult murine hematopoiesis. Proc. Natl. Acad. Sci. U.S.A. 102, 18105-18110.

[0155] Becht, E., McInnes, L., Healy, J., Dutertre, C.-A. C.-A., Kwok, I. W. H. I. W. H., Ng, L. G. L. G., Ginhoux, F., and Newell, E. W. E. W. (2018). Dimensionality reduction for visualizing single-cell data using UMAP. Nat. Biotechnol. 37, 38-44.

[0156] Chen E Y, Tan C M, Kou Y, Duan O, Wang Z, Meirelles G V, et al. Enrichr: Interactive and collaborative HTML5 gene list enrichment analysis tool. BMC Bioinformatics. 2013 Apr.; 14.

[0157] Chong, S. Z., Evrard, M., Devi, S., Chen, J., Lim, J. Y., See, P., Zhang, Y., Adrover, J. M., Lee, B., Tan, L., et al. (2016). CXCR4 identifies transitional bone marrow premonocytes that replenish the mature monocyte pool for peripheral responses. J. Exp. Med. 213, 2293-2314.

[0158] Dutertre, C.-A., Becht, E., Erdal, S., Radstake, T., and Newell, E. W. (2019). Single-Cell Analysis of Human Mononuclear Phagocytes Reveals Subset-Defining Markers and Identifies Circulating Inflammatory Dendritic Cells CD14+ / À DC3s d Pro-inflammatory CD14+DC3 expansion correlates with disease activity in SLE patients. Immunity.

[0159] Giladi, A., Paul, F., Herzog, Y., Lubling, Y., Weiner, A., Yofe, I., Jaitin, D., Cabezas-Wallscheid, N., Dress, R., Ginhoux, F., et al. (2018). Single-cell characterization of haematopoietic progenitors and their trajectories in homeostasis and perturbed haematopoiesis. Nat. Cell Biol. 20.

[0160] Hettinger, J., Richards, D. M., Hansson, J., Barra, M. M., Joschko, A.-C., Krijgsveld, J., and Feuerer, M. (2013). Origin of monocytes and macrophages in a committed progenitor. Nat. Immunol. 14, 821-830.

[0161] Kyme P, Thoennissen N H, Tseng C W, Thoennissen G B, Wolf A J, Shimada K, et al. C / EBPE mediates nicotinamide-enhanced clearance of Staphylococcus aureus in mice. Journal of Clinical Investigation. 2012 September; 122(9):3316-29.

[0162] Iwasaki, H., Mizuno, S., Mayfield, R., Shigematsu, H., Arinobu, Y., Seed, B., Gurish, M. F., Takatsu, K., and Akashi, K. (2005). Identification of eosinophil lineage-committed progenitors in the murine bone marrow. J. Exp. Med. 201, 1891-1897.

[0163] Levine, J. H., Simonds, E. F., Bendall, S. C., Downing, J. R., Pe'er, D., and Correspondence, G. P. N. (2015). Data-Driven Phenotypic Dissection of AML Reveals Progenitor-like Cells that Correlate with Prognosis. Cell 162, 184-197.

[0164] Maaten, L., and Hinton, G. (2008). Visualizing data using t-SNE. J. Mach. Learn. Res.

[0165] McInnes, L., Healy, J., and Melville, J. (2018). UMAP: Uniform Manifold Approximation and Projection for Dimension Reduction.

[0166] Olsson, A., Venkatasubramanian, M., Chaudhri, V. K., Aronow, B. J., Salomonis, N., Singh, H., Grimes, H. L., and Leighton Grimes, H. (2016). Single-cell analysis of mixed-lineage states leading to a binary cell fate choice. Nature 537, 698-702.

[0167] Picelli, S., Faridani, O. R., Björklund, Å. K., Winberg, G., Sagasser, S., and Sandberg, R. (2014). Full-length RNA-seq from single cells using Smart-seq2. Nat. Protoc. 9, 171-181.

[0168] Qiu, X., Mao, Q., Tang, Y., Wang, L., Chawla, R., Pliner, H. A., and Trapnell, C. (2017). Reversed graph embedding resolves complex single-cell trajectories. Nat. Methods 14, 979-982.

[0169] Rittirsch, D., Huber-Lang, M. S., Flierl, M. A., and Ward, P. A. (2009). Immunodesign of experimental sepsis by cecal ligation and puncture. Nat. Protoc. 4, 31-36.

[0170] Robinson, M. D., McCarthy, D. J., and Smyth, G. K. (2009). edgeR: A Bioconductor package for differential expression analysis of digital gene expression data. Bioinformatics 26, 139-140.

[0171] Rubinstein, M. P., Salem, M. L., Doedens, A. L., Moore, C. J., Chiuzan, C., Rivell, G. L., Cole, D. J., and Goldrath, A. W. (2013). G-CSF / anti-G-CSF antibody complexes drive the potent recovery and expansion of CD11b+Gr-1+myeloid cells without compromising CD8+T cell immune responses. Journal of Hematology & Oncology 6, 75.

[0172] Sakaue-Sawano, A., Kurokawa, H., Morimura, T., Hanyu, A., Hama, H., Osawa, H., Kashiwagi, S., Fukami, K., Miyata, T., Miyoshi, H., et al. (2008). Visualizing Spatiotemporal Dynamics of Multicellular Cell-Cycle Progression. Cell 132, 487-498.

[0173] Schaum, N., Karkanias, J., Neff, N. F., May, A. P., Quake, S. R., Wyss-Coray, T., Darmanis, S., Batson, J., Botvinnik, O., Chen, M. B., et al. (2018). Single-cell transcriptomics of 20 mouse organs creates a Tabula Muris the tabula Muris consortium*.

[0174] Stuart, T., Butler, A., Hoffman, P., Hafemeister, C., Papalexi, E., Mauck III, W. M., Stoeckius, M., Smibert, P., and Satija, R. (2018). Comprehensive integration of single cell data. 1-24.

[0175] Tomura, M., Sakaue-Sawano, A., Mori, Y., Takase-Utsugi, M., Hata, A., Ohtawa, K., Kanagawa, O., and Miyawaki, A. (2013). Contrasting Quiescent G0 Phase with Mitotic Cell Cycling in the Mouse Immune System. PLoS One 8, e73801-10.

[0176] Van Der Maaten L, Hinton G. Visualizing data using t-SNE. Journal of Machine Learning Research. 2008; 9:2579-625.

[0177] Yamanaka, R., Barlow, C., Lekstrom-Himes, J., Castilla, L. H., Liu, P. P., Eckhaus, M., Decker, T., Wynshaw-Boris, A., and Xanthopoulos, K. G. (1997). Impaired granulopoiesis, myelodysplasia, and early lethality in CCAAT / enhancer binding protein ε-deficient mice. Proc. Natl. Acad. Sci. U.S.A 94, 13187-13192.

[0178] It will be appreciated by a person skilled in the art that other variations and / or modifications may be made to the embodiments disclosed herein without departing from the spirit or scope of the disclosure as broadly described. For example, in the description herein, features of different exemplary embodiments may be mixed, combined, interchanged, incorporated, adopted, modified, included etc. or the like across different exemplary embodiments. The present embodiments are, therefore, to be considered in all respects to be illustrative and not restrictive.

Claims

1. A method of identifying neutrophil progenitors, the method comprising:determining an expression of the following biomarkers: CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and CD49d in a cell;identifying the cell as an early neutrophil progenitor when it is determined to have the following expression profiles: CD71hi / +, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / − TACSTD2hi / +, CD11blo / − and CD49dint / hi / +;selecting the cell identified as the early neutrophil progenitor;determining an expression of the selected cell of a further biomarker CD49d and a side-scatter (SSC) property of the neutrophil progenitor;identifying the cell as an early committed neutrophil progenitor or an intermediate neutrophil progenitor subtype based on the expression of the further biomarker and the side-scatter property,wherein where the cell is determined to be CD71hi / +, CD49dhi / + and SSClo, the cell is identified as an early committed neutrophil progenitor, andwherein where the cell is determined to be CD71hi / +, CD49dint / lo / − and SSChi, the cell is identified as an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor,wherein the method further comprising culturing the identified neutrophil progenitors to obtain proliferation and / or differentiation of the neutrophil progenitors to obtain progenies thereof, andadministering the neutrophil progenitors and / or the progenies thereof to a subject in need thereof.

2. The method according to claim 1, wherein determination of the expression of the biomarkers and the further biomarker comprises contacting the cell with antibodies against the biomarkers and the further biomarker.

3. A method of sorting and / or separating neutrophil progenitors from a cell population, the method comprising:selecting the cell having the following expression profiles: CD71hi / +, LOX-1int / lo / − CD164hi / +, CD112hi / +, CD181int / lo / − TACSTD2hi / +, CD11blo / − and CD49dint / hi / +;determining an expression of the selected cells of a further biomarker CD49d and a side-scatter (SSC) property;identifying the cells as an early committed neutrophil progenitor or an intermediate neutrophil progenitor subtype based on the expression of the further biomarker and the side-scatter property;sorting and / or separating the identified cells as an early committed neutrophil progenitor having the following expression profiles: CD71hi / +, CD49dhi / + and SSClo; andsorting and / or separating the identified cells as an intermediate neutrophil progenitor having the following expression profiles: CD71hi / +, CD49d int / lo / − and SSChi.

4. The method according to claim 3, wherein the cell population is derived from cord blood and / or bone marrow.

5. The method according to claim 3, the method further comprising culturing the neutrophil progenitors to obtain proliferation and / or differentiation of the neutrophil progenitors to obtain progenies thereof.

6. The method according to claim 3, the method further comprising administering the neutrophil progenitors and / or the progenies thereof to a subject in need thereof.

7. The method according to claim 6, wherein the subject has neutropenia.

8. The method according to claim 3, wherein the selecting comprises contacting the cells with antibodies against CD71, LOX-1, CD164, CD112, CD181, TACSTD2, CD11b and CD49d.

9. A composition that is enriched in early neutrophil progenitors having the following expression profiles: CD71hi / +, CD49dhi / +, SSClo, LOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, and CD11blo / −.

10. The method of claim 3, further comprising preparing a transfusion composition, wherein the composition is an enriched composition of early neutrophil progenitors having CD71hi / + CD49dhi+, SSCloLOX-1int / lo / −, CD164hi / +, CD112hi / +, CD181int / lo / −, TACSTD2hi / +, and CD11blo / −.

11. The composition of claim 9, further comprising an intermediate neutrophil progenitor that is downstream in neutrophil lineage to the early committed neutrophil progenitor having the following expression profile: CD71hi / 30 , CD49dint / lo / − and SSChi.